Quantitative trait loci affecting fatty acid composition in milk

ABSTRACT

The present invention relates to polymorphisms indicative of altered milk fatty acid composition in female milk-producing cattle. In particular, the present invention provides methods for selecting a cattle which possesses a genotype which in female milk-producing cattle is indicative of a desired milk fatty acid composition and cattle selected by said method. Further, the present invention provides milk produced by the female milk-producing cattle, methods for selective breeding and non-human gametes. Use of a nucleic acid molecule or an oligonucleotide in an in vitro method for determining the presence of at least one allele, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, is also part of the present invention.

FIELD OF THE INVENTION

The present invention relates to polymorphisms indicative of altered milk fatty acid composition in female milk-producing cattle. In particular, the present invention provides methods for selecting a cattle which possesses a genotype which in female milk-producing cattle is indicative of a desired milk fatty acid composition and cattle selected by said method. Further, the present invention provides milk produced by the female milk-producing cattle, methods for selective breeding and non-human gametes. Use of a nucleic acid molecule or an oligonucleotide in an in vitro method for determining the presence of at least one allele, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, is also part of the present invention.

BACKGROUND OF THE INVENTION

Bovine milk is widely regarded as a valuable food source in human nutrition, and serves as an important source of proteins, minerals, vitamins and fats in western diets. In addition to being an important source of energy, the milk fat contains valuable fat-soluble vitamins and bio-active lipid components.

Of the roughly 400 different fatty acids found in Bovine milk, only around 15 are present at the 1% level or higher. The milk fatty acids are derived via two major pathways: direct transport from rumen to mammary gland by the blood, and de novo synthesis in the mammary gland. The short- and medium-chained saturated fatty acids C4:0 to C14:0 together with about half of the C16:0 are synthesized de novo in the mammary gland from acetate and β-hydroxybutyrate. Acetate and butyric acid are generated in the rumen by fermentation of feed components and butyric acid is converted to β-hydroxybutyrate during absorption through the rumen epithelium. The remaining C16:0 and the long-chain fatty acids typically originate from dietary lipids and from lipolysis of adipose tissue triacylglycerols.

Both the long- and medium-chained fatty acids may be desaturated by Δ⁹-desaturase to their cis-9 monounsaturated counterparts. Monounsaturated fatty acids constitutes approximately 25% of the fatty acids in milk, with oleic acid (18:1) accounting for about 24% by weight of the total fatty acids. Poly-unsaturated fatty acids constitutes about 2% by weight of the total fatty acids and the main poly-unsaturated fatty acids are linoleic acid (18:2) and α-linolenic acid (18:3) accounting for 1.6 and 0.7% by weight of the total fatty acids.

Due to ruminal biohydrogenation of unsaturated fatty acids from the diet, the saturated fatty acids present in milk account for approximately 70% by weight of the total fatty acids. The most important saturated fatty acid from a quantitative viewpoint is palmitic acid (16:0), which accounts for approximately 30% by weight. Myristic acid (14:0) and stearic acid (18:0) make up 11 and 12% by weight, respectively. Of the saturated fatty acids, about 10.9% are short-chain fatty acids (C4:0-C10:0).

The net effect of dairy fat on human health is debated because while mono- and polyunsaturated fatty acids as well as short saturated fatty acids typically have been associated with positive effects on cardiovascular health and diabetes, medium and long-chain saturated fatty acids have been associated with cardiovascular disease and obesity. It is therefore of great interest to identify factors that may influence fatty acid composition in bovine milk.

Many factors are known to be associated with variations in the amount and fatty acid composition of bovine milk lipids. They may be of animal origin, i.e. related to genetics (breeding and selection), stage of lactation, mastitis and ruminal fermentation, or they may be feed-related factors, i.e. related to fiber and energy intake, dietary fats, and seasonal and regional effects.

The present inventors have identified factors of animal origin, i.e. related to genetics that influence the fatty acid composition of bovine milk. The factors identified are polymorphisms, including single nucleotide polymorphisms (SNP), within the bovine genome which in a female milk-producing cattle influence the milk fatty acid composition.

SUMMARY OF THE INVENTION

Method for Selecting a Cattle

The present invention provides in a first aspect a method for selecting a cattle which possesses a genotype which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, the method comprising:

determining the presence of at least one allele, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle; and

selecting said cattle when the at least one allele, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, is present.

According to particular embodiments, the at least one allele is an allele of at least one polymorphism selected from the polymorphisms listed in table 1. The at least one allele is preferably an allele of at least one polymorphism selected from the group consisting of P #1 to P #916, such as P #1 to P #310.

According to other particular embodiments, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #1 to P #916, such as P #1 to P #310.

According to other particular embodiments, a desired milk fatty acid composition is decreased amount of C16:0 in milk; increased amount of C18:1 in milk; increased amount of C14:1 cis-9 in milk; increased amount of one or more fatty acids selected from the group consisting of C6:0, C8:0, C10:0, C12:0 and C14:0 in milk; or any combination thereof.

According to other particular embodiments, the at least one allele is a non-fat allele” for C16:0 of at least one polymorphism selected from the polymorphisms listed in table 1; “fat allele” for C18:1 of at least one polymorphism selected from the polymorphisms listed in table 1; “fat allele” for C14:1 cis-9 of at least one polymorphism selected from the polymorphisms listed in table 1; “fat allele” for C6:0 of at least one polymorphism selected from the polymorphisms listed in table 1; “fat allele” for C8:0 of at least one polymorphism selected from the polymorphisms listed in table 1; “fat allele” for C10:0 of at least one polymorphism selected from the polymorphisms listed in table 1; “fat allele” for C12:0 of at least one polymorphism selected from the polymorphisms listed in table 1; “fat allele” for C14:0 of at least one polymorphism selected from the polymorphisms listed in table 1; or any combination thereof.

According to other particular embodiments, the at least one allele is:

a “non-fat allele” for C16:0 of at least one polymorphism selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481;

a “fat allele” for C18:1 of at least one polymorphism selected from the group consisting of P #19, P #34, P #38, P #39, P #141, P #148, P #153, P #233-P #240, P #242-P #246, P #271-P #278, P #280-P #283, P #285, P #289-P #302, P #311-P #334, P #339, P #340, P #343-P #475, P #477-P #481, P #484-P #494, P #497, P #543, P #588, P #589, P #916, P #911, P #14, P #37, P #903 and P #7;

a “fat allele” for C14:1 cis-9 of at least one polymorphism selected from the group consisting of P #243-P #246, P #314-P #332, P #334-P #340, P #346-P #352, P #354-P #363, P #366-P #392, P #394-P #396, P #398-P #410, P #412-P #475 and P #477-P #481;

a “fat allele” for C6:0 of at least one polymorphism selected from the group consisting of P #1, P #12, P #15-P #17, P #24, P #41, P #63, P #64, P #69-P #71, P #74-P #79, P #83, P #85-P #87, P #89-P #93, P #97-P #103, P #112-P #118, P #120, P #121, P #123-P #135, P #138-P #141, P #148, P #153-P #168, P #218, P #220-P #226, P #249, P #250, P #253-P #260, P #267, P #495, P #499, P #501, P #503-P #514, P #517-P #539, P #541, P #542, P #544-P #547, P #554-P #585, P #590-P #592, P #595-P #597, P #599-P #614, P #617-P #621, P #623-P #652, P #654-P #669, P #672-P #674, P #676-P #678, P #681, P #682, P #688-P #744, P #746-P #769, P #771-P #813, P #815, P #818-P #824, P #826-P #831 and P #872;

a “fat allele” for C8:0 of at least one polymorphism selected from the group consisting of P #1, P #10-P #12, P #16-P #19, P #40-P #45, P #48, P #49, P #51, P #56-P #60, P #63-P #66, P #68-P #93, P #97, P #99-P #101, P #103-P #108, P #111-P #118, P #120, P #121, P #123-P #218, P #220, P #224-P #231, P #254, P #258, P #259, P #268, P #270, P #285-P #288, P #302, P #495, P #496, P #498-P #539, P #541-P #551, P #554-P #586, P #590-P #594, P #628, P #682 and P #683;

a “fat allele” for C10:0 of at least one polymorphism selected from the group consisting of P #3, P #8-P #10, P #16-P #20, P #49-P #51, P #56-P #62, P #64, P #69-P #72, P #74, P #76-P #78, P #80-P #96, P #104-P #109, P #111-P #115, P #117, P #118, P #120, P #121, P #127, P #128, P #132, P #133, P #136-P #142, P #148-P #153, P #156-P #166, P #224-P #226, P #285-P #288, P #297-P #302, P #490-P #494, P #501-P #514, P #517-P #539, P #541-P #547, P #551, P #554-P #580, P #585, P #586, P #589-P #593, P #628, P #889-P #891, P #899, P #900, P #902-P #916;

a “fat allele” for C12:0 of at least one polymorphism selected from the group consisting of P #3, P #9, P #10, P #16-P #20, P #49-P #53, P #61, P #62, P #64, P #67, P #69-P #72, P #74, P #83, P #85-P #87, P #89-P #96, P #104-P #113, P #115, P #117-P #122, P #127, P #128, P #132, P #133, P #138, P #139, P #141, P #142, P #148-P #151, P #153, P #219, P #224-P #226, P #276, P #285-P #288, P #290-P #302, P #487-P #495, P #497, P #501-P #515, P #517-P #547, P #551, P #554-P #580, P #585, P #586, P #588-P #594, P #887-P #891, P #893-P #916;

a “fat allele” for C14:0 of at least one polymorphism selected from the group consisting of P #9, P #10, P #17-P #19, P #34, P #69, P #70, P #83, P #85, P #117, P #120, P #121, P #127, P #128, P #132, P #133, P #139, P #141, P #148-P #151, P #153, P #224-P #226, P #275, P #276, P #279-P #281, P #284-P #302, P #483-P #494, P #497, P #501-P #514, P #517-P #539, P #541, P #543-P #580, P #584-P #594, P #889-P #892, P #899, P #900, P #902-P #916; or

any combination thereof.

According to other particular embodiments, the at least one allele is a “non-fat allele” for C16:0 of at least one polymorphism selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481.

The presence of a “fat-allele” for a specific trait is indicative of increased amount of that trait in milk; and the presence of a “non-fat allele” for a specific trait is indicative of decreased amount of that trait in milk. “fat allele”, “non-fat allele” and the respective traits are specified in table 1.

According to other particular embodiments, the present invention provides a method for selecting a cattle which possesses a genotype which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, the method comprising:

determining the identity of one or more nucleotides of at least one allele of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NOs: 1 to 916, such as SEQ ID NOs: 1 to 310; or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NOs: 1 to 916, such as SEQ ID NOs: 1 to 310, by 1 to 30 nucleotide substitutions; and

selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of the desired milk fatty acid composition.

Other particular embodiments relates to a method for selecting a cattle which possesses a genotype which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, the method comprising:

determining the identity of one or more nucleotides of at least one allele of at least one polymorphism, which in a female milk-producing cattle is indicative of decreased amount of C16:0 in milk, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NO 33, 241-248, 303-312, 314-344, 346-475 and 477-481; or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NO 33, 241-248, 303-312, 314-344, 346-475 and 477-481 by 1 to 30 nucleotide substitutions; and

selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the “non-fat allele” for C16:0.

Non-Human Gamete

The present invention provides in a second aspect a non-human gamete, such as an isolated non-human gamete, comprising within its genome at least one allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition.

According to particular embodiments, the at least one allele is an allele of at least one polymorphism. The at least one polymorphism may be selected from the polymorphisms listed in table 1.

According to other particular embodiments, the at least one allele is:

a “non-fat allele” for C16:0 of at least one polymorphism selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481;

a “fat allele” for C18:1 of at least one polymorphism selected from the group consisting of P #19, P #34, P #38, P #39, P #141, P #148, P #153, P #233-P #240, P #242-P #246, P #271-P #278, P #280-P #283, P #285, P #289-P #302, P #311-P #334, P #339, P #340, P #343-P #475, P #477-P #481, P #484-P #494, P #497, P #543, P #588, P #589, P #916, P #911, P #14, P #37, P #903 and P #7;

a “fat allele” for C14:1 cis-9 of at least one polymorphism selected from the group consisting of P #243-P #246, P #314-P #332, P #334-P #340, P #346-P #352, P #354-P #363, P #366-P #392, P #394-P #396, P #398-P #410, P #412-P #475 and P #477-P #481;

a “fat allele” for C6:0 of at least one polymorphism selected from the group consisting of P #1, P #12, P #15-P #17, P #24, P #41, P #63, P #64, P #69-P #71, P #74-P #79, P #83, P #85-P #87, P #89-P #93, P #97-P #103, P #112-P #118, P #120, P #121, P #123-P #135, P #138-P #141, P #148, P #153-P #168, P #218, P #220-P #226, P #249, P #250, P #253-P #260, P #267, P #495, P #499, P #501, P #503-P #514, P #517-P #539, P #541, P #542, P #544-P #547, P #554-P #585, P #590-P #592, P #595-P #597, P #599-P #614, P #617-P #621, P #623-P #652, P #654-P #669, P #672-P #674, P #676-P #678, P #681, P #682, P #688-P #744, P #746-P #769, P #771-P #813, P #815, P #818-P #824, P #826-P #831 and P #872;

a “fat allele” for C8:0 of at least one polymorphism selected from the group consisting of P #1, P #10-P #12, P #16-P #19, P #40-P #45, P #48, P #49, P #51, P #56-P #60, P #63-P #66, P #68-P #93, P #97, P #99-P #101, P #103-P #108, P #111-P #118, P #120, P #121, P #123-P #218, P #220, P #224-P #231, P #254, P #258, P #259, P #268, P #270, P #285-P #288, P #302, P #495, P #496, P #498-P #539, P #541-P #551, P #554-P #586, P #590-P #594, P #628, P #682 and P #683;

a “fat allele” for C10:0 of at least one polymorphism selected from the group consisting of P #3, P #8-P #10, P #16-P #20, P #49-P #51, P #56-P #62, P #64, P #69-P #72, P #74, P #76-P #78, P #80-P #96, P #104-P #109, P #111-P #115, P #117, P #118, P #120, P #121, P #127, P #128, P #132, P #133, P #136-P #142, P #148-P #153, P #156-P #166, P #224-P #226, P #285-P #288, P #297-P #302, P #490-P #494, P #501-P #514, P #517-P #539, P #541-P #547, P #551, P #554-P #580, P #585, P #586, P #589-P #593, P #628, P #889-P #891, P #899, P #900, P #902-P #916;

a “fat allele” for C12:0 of at least one polymorphism selected from the group consisting of P #3, P #9, P #10, P #16-P #20, P #49-P #53, P #61, P #62, P #64, P #67, P #69-P #72, P #74, P #83, P #85-P #87, P #89-P #96, P #104-P #113, P #115, P #117-P #122, P #127, P #128, P #132, P #133, P #138, P #139, P #141, P #142, P #148-P #151, P #153, P #219, P #224-P #226, P #276, P #285-P #288, P #290-P #302, P #487-P #495, P #497, P #501-P #515, P #517-P #547, P #551, P #554-P #580, P #585, P #586, P #588-P #594, P #887-P #891, P #893-P #916;

a “fat allele” for C14:0 of at least one polymorphism selected from the group consisting of P #9, P #10, P #17-P #19, P #34, P #69, P #70, P #83, P #85, P #117, P #120, P #121, P #127, P #128, P #132, P #133, P #139, P #141, P #148-P #151, P #153, P #224-P #226, P #275, P #276, P #279-P #281, P #284-P #302, P #483-P #494, P #497, P #501-P #514, P #517-P #539, P #541, P #543-P #580, P #584-P #594, P #889-P #892, P #899, P #900, P #902-P #916; or any combination thereof.

According to other particular embodiments, the at least one allele is a “non-fat allele” for C16:0 of at least one polymorphism selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481.

According to other particular embodiments, the gamete comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NO:33, 241-248, 303-312, 314-344, 346-475 and 477-481; and b) nucleotide sequences which are derived from any one of SEQ ID NO:33, 241-248, 303-312, 314-344, 346-475 and 477-481 by 1 to 30 nucleotide substitutions;

wherein the one or more nucleotides at position 60 of the nucleotide sequence set forth in any one of SEQ ID NO:33, 241-248, 303-312, 314-344, 346-475 and 477-481 corresponds to the “non-fat allele” for C16:0.

According to other particular embodiments, said non-human gamete is non-human semen or non-human sperm.

According to other particular embodiments, said non-human gamete is non-human ovum.

Method for Selective Breeding

The present invention provides in a third aspect a method for selective breeding of a cattle, the method comprises:

providing non-human semen or non-human sperm comprising within its genome at least one allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition; and

fertilizing a female (milk-producing) cattle using the non-human semen or non-human sperm.

According to particular embodiments, the present invention provides a method for determining the presence of at least one allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition within the genome of a female (milk-producing) cattle;

selecting the female (milk-producing) cattle when the at least one allele, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, is present;

providing non-human semen or non-human sperm comprising within its genome at least one allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition;

fertilizing the selected female (milk-producing) cattle using the non-human semen or non-human sperm according to the second aspect of the present invention.

According to other particular embodiments, the at least one allele is an allele of at least one polymorphism. The at least one polymorphism may be selected from the polymorphisms listed in table 1.

According to other particular embodiments, the at least one allele is:

a “non-fat allele” for C16:0 of at least one polymorphism selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481;

a “fat allele” for C18:1 of at least one polymorphism selected from the group consisting of P #19, P #34, P #38, P #39, P #141, P #148, P #153, P #233-P #240, P #242-P #246, P #271-P #278, P #280-P #283, P #285, P #289-P #302, P #311-P #334, P #339, P #340, P #343-P #475, P #477-P #481, P #484-P #494, P #497, P #543, P #588, P #589, P #916, P #911, P #14, P #37, P #903 and P #7;

a “fat allele” for C14:1 cis-9 of at least one polymorphism selected from the group consisting of P #243-P #246, P #314-P #332, P #334-P #340, P #346-P #352, P #354-P #363, P #366-P #392, P #394-P #396, P #398-P #410, P #412-P #475 and P #477-P #481;

a “fat allele” for C6:0 of at least one polymorphism selected from the group consisting of P #1, P #12, P #15-P #17, P #24, P #41, P #63, P #64, P #69-P #71, P #74-P #79, P #83, P #85-P #87, P #89-P #93, P #97-P #103, P #112-P #118, P #120, P #121, P #123-P #135, P #138-P #141, P #148, P #153-P #168, P #218, P #220-P #226, P #249, P #250, P #253-P #260, P #267, P #495, P #499, P #501, P #503-P #514, P #517-P #539, P #541, P #542, P #544-P #547, P #554-P #585, P #590-P #592, P #595-P #597, P #599-P #614, P #617-P #621, P #623-P #652, P #654-P #669, P #672-P #674, P #676-P #678, P #681, P #682, P #688-P #744, P #746-P #769, P #771-P #813, P #815, P #818-P #824, P #826-P #831 and P #872;

a “fat allele” for C8:0 of at least one polymorphism selected from the group consisting of P #1, P #10-P #12, P #16-P #19, P #40-P #45, P #48, P #49, P #51, P #56-P #60, P #63-P #66, P #68-P #93, P #97, P #99-P #101, P #103-P #108, P #111-P #118, P #120, P #121, P #123-P #218, P #220, P #224-P #231, P #254, P #258, P #259, P #268, P #270, P #285-P #288, P #302, P #495, P #496, P #498-P #539, P #541-P #551, P #554-P #586, P #590-P #594, P #628, P #682 and P #683;

a “fat allele” for C10:0 of at least one polymorphism selected from the group consisting of P #3, P #8-P #10, P #16-P #20, P #49-P #51, P #56-P #62, P #64, P #69-P #72, P #74, P #76-P #78, P #80-P #96, P #104-P #109, P #111-P #115, P #117, P #118, P #120, P #121, P #127, P #128, P #132, P #133, P #136-P #142, P #148-P #153, P #156-P #166, P #224-P #226, P #285-P #288, P #297-P #302, P #490-P #494, P #501-P #514, P #517-P #539, P #541-P #547, P #551, P #554-P #580, P #585, P #586, P #589-P #593, P #628, P #889-P #891, P #899, P #900, P #902-P #916;

a “fat allele” for C12:0 of at least one polymorphism selected from the group consisting of P #3, P #9, P #10, P #16-P #20, P #49-P #53, P #61, P #62, P #64, P #67, P #69-P #72, P #74, P #83, P #85-P #87, P #89-P #96, P #104-P #113, P #115, P #117-P #122, P #127, P #128, P #132, P #133, P #138, P #139, P #141, P #142, P #148-P #151, P #153, P #219, P #224-P #226, P #276, P #285-P #288, P #290-P #302, P #487-P #495, P #497, P #501-P #515, P #517-P #547, P #551, P #554-P #580, P #585, P #586, P #588-P #594, P #887-P #891, P #893-P #916;

a “fat allele” for C14:0 of at least one polymorphism selected from the group consisting of P #9, P #10, P #17-P #19, P #34, P #69, P #70, P #83, P #85, P #117, P #120, P #121, P #127, P #128, P #132, P #133, P #139, P #141, P #148-P #151, P #153, P #224-P #226, P #275, P #276, P #279-P #281, P #284-P #302, P #483-P #494, P #497, P #501-P #514, P #517-P #539, P #541, P #543-P #580, P #584-P #594, P #889-P #892, P #899, P #900, P #902-P #916; or

any combination thereof.

According to other particular embodiments, the at least one allele is a “non-fat allele” for C16:0 of at least one polymorphism selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481.

According to particular embodiments, the present invention provides a method for selective breeding of a cattle, the method comprises:

determining the identity of one or more nucleotides of at least one allele of at least one polymorphism, which in a female milk-producing cattle is indicative of decreased amount of C16:0 in milk, within the genome of a (suitable) female (milk-producing) cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NO 33, 241-248, 303-312, 314-344, 346-475 and 477-481; or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NO 33, 241-248, 303-312, 314-344, 346-475 and 477-481 by 1 to 30 nucleotide substitutions; and

selecting said female (milk-producing) cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the “non-fat allele” for C16:0;

providing non-human semen or non-human sperm comprising within its genome at least one allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition; and

fertilizing the selected female (milk-producing) cattle using the non-human semen or non-human sperm.

In Vitro Method for Selective Breeding

The present invention provides in a fourth aspect a method for selective breeding of a cattle, the method comprises:

in vitro fertilizing the non-human ovum according to the second aspect of the present invention using the non-human semen or non-human sperm according to the second aspect of the present invention; and

implanting the in vitro fertilized non-human ovum in the uterus of a female (milk-producing) cattle.

Cattle

The present invention provides in a fifth aspect, a cattle obtainable by the method according to the first aspect of the present invention, the method according to the third aspect of the present invention or the method according to the fourth aspect of the present invention.

The present invention further provides in a sixth aspect, a cattle comprising within its genome at least one allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition.

The at least one allele may be an allele of at least one polymorphism. The at least one polymorphism may be selected from the polymorphisms listed in table 1.

According to particular embodiments, the at least one allele is:

a “non-fat allele” for C16:0 of at least one polymorphism selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481;

a “fat allele” for C18:1 of at least one polymorphism selected from the group consisting of P #19, P #34, P #38, P #39, P #141, P #148, P #153, P #233-P #240, P #242-P #246, P #271-P #278, P #280-P #283, P #285, P #289-P #302, P #311-P #334, P #339, P #340, P #343-P #475, P #477-P #481, P #484-P #494, P #497, P #543, P #588, P #589, P #916, P #911, P #14, P #37, P #903 and P #7;

a “fat allele” for C14:1 cis-9 of at least one polymorphism selected from the group consisting of P #243-P #246, P #314-P #332, P #334-P #340, P #346-P #352, P #354-P #363, P #366-P #392, P #394-P #396, P #398-P #410, P #412-P #475 and P #477-P #481;

a “fat allele” for C6:0 of at least one polymorphism selected from the group consisting of P #1, P #12, P #15-P #17, P #24, P #41, P #63, P #64, P #69-P #71, P #74-P #79, P #83, P #85-P #87, P #89-P #93, P #97-P #103, P #112-P #118, P #120, P #121, P #123-P #135, P #138-P #141, P #148, P #153-P #168, P #218, P #220-P #226, P #249, P #250, P #253-P #260, P #267, P #495, P #499, P #501, P #503-P #514, P #517-P #539, P #541, P #542, P #544-P #547, P #554-P #585, P #590-P #592, P #595-P #597, P #599-P #614, P #617-P #621, P #623-P #652, P #654-P #669, P #672-P #674, P #676-P #678, P #681, P #682, P #688-P #744, P #746-P #769, P #771-P #813, P #815, P #818-P #824, P #826-P #831 and P #872;

a “fat allele” for C8:0 of at least one polymorphism selected from the group consisting of P #1, P #10-P #12, P #16-P #19, P #40-P #45, P #48, P #49, P #51, P #56-P #60, P #63-P #66, P #68-P #93, P #97, P #99-P #101, P #103-P #108, P #111-P #118, P #120, P #121, P #123-P #218, P #220, P #224-P #231, P #254, P #258, P #259, P #268, P #270, P #285-P #288, P #302, P #495, P #496, P #498-P #539, P #541-P #551, P #554-P #586, P #590-P #594, P #628, P #682 and P #683;

a “fat allele” for C10:0 of at least one polymorphism selected from the group consisting of P #3, P #8-P #10, P #16-P #20, P #49-P #51, P #56-P #62, P #64, P #69-P #72, P #74, P #76-P #78, P #80-P #96, P #104-P #109, P #111-P #115, P #117, P #118, P #120, P #121, P #127, P #128, P #132, P #133, P #136-P #142, P #148-P #153, P #156-P #166, P #224-P #226, P #285-P #288, P #297-P #302, P #490-P #494, P #501-P #514, P #517-P #539, P #541-P #547, P #551, P #554-P #580, P #585, P #586, P #589-P #593, P #628, P #889-P #891, P #899, P #900, P #902-P #916;

a “fat allele” for C12:0 of at least one polymorphism selected from the group consisting of P #3, P #9, P #10, P #16-P #20, P #49-P #53, P #61, P #62, P #64, P #67, P #69-P #72, P #74, P #83, P #85-P #87, P #89-P #96, P #104-P #113, P #115, P #117-P #122, P #127, P #128, P #132, P #133, P #138, P #139, P #141, P #142, P #148-P #151, P #153, P #219, P #224-P #226, P #276, P #285-P #288, P #290-P #302, P #487-P #495, P #497, P #501-P #515, P #517-P #547, P #551, P #554-P #580, P #585, P #586, P #588-P #594, P #887-P #891, P #893-P #916;

a “fat allele” for C14:0 of at least one polymorphism selected from the group consisting of P #9, P #10, P #17-P #19, P #34, P #69, P #70, P #83, P #85, P #117, P #120, P #121, P #127, P #128, P #132, P #133, P #139, P #141, P #148-P #151, P #153, P #224-P #226, P #275, P #276, P #279-P #281, P #284-P #302, P #483-P #494, P #497, P #501-P #514, P #517-P #539, P #541, P #543-P #580, P #584-P #594, P #889-P #892, P #899, P #900, P #902-P #916; or

any combination thereof.

According to other particular embodiments, the at least one allele is a “non-fat allele” for C16:0 of at least one polymorphism selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481.

According to particular embodiments, said cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) a nucleotide sequence set forth in any one of SEQ ID NO 33, 241-248, 303-312, 314-344, 346-475 and 477-481; and b) nucleotide sequences which are derived from any one of SEQ ID NO 33, 241-248, 303-312, 314-344, 346-475 and 477-481; by 1 to 30 nucleotide substitutions;

wherein the one or more nucleotides at position 60 of the nucleotide sequence set forth in any one of SEQ ID NO 33, 241-248, 303-312, 314-344, 346-475 and 477-481; corresponds to the “non-fat allele” for C16:0.

In one embodiment according to the fifth or sixth aspect of the present invention, said cattle is a (isolated) male cattle.

In another embodiment according to the fifth or sixth aspect of the present invention, said cattle is a (isolated) female milk-producing cattle.

Milk

A seventh aspect of the present invention, relates to milk produced by the (isolated) female milk-producing cattle according to the fifth or sixth aspect of the present invention.

Use

The present invention provides in an eighth aspect, use of an (isolated) nucleic acid molecule in an in vitro method for determining the presence of at least one allele, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of a cattle;

wherein the (isolated) nucleic acid molecule comprises at least one nucleotide sequence selected from the group consisting of a) a nucleotide sequence set forth in any one of SEQ ID NO: 1 to 916, such as SEQ ID NOs: 1 to 310; b) a nucleotide sequence derived from any one of SEQ ID NO: 1 to 916, such as SEQ ID NOs: 1 to 310, by 1 to 30 nucleotide substitutions; and c) complements to a) and b); the one or more nucleotides at position 60 of said nucleotide sequences being selected from the two alternative forms of the allele to be determined.

The present invention provides in a ninth aspect, use of an (isolated) oligonucleotide in an in vitro method for determining the presence of at least one allele, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of a cattle;

wherein the (isolated) oligonucleotide comprises at least 20 contiguous nucleotides of a nucleotide sequence selected from the group consisting of a) a nucleotide sequence set forth in any one of SEQ ID NO: 1 to 916, such as SEQ ID NOs: 1 to 310; b) a nucleotide sequence derived from any one of SEQ ID NO: 1 to 916, such as SEQ ID NOs: 1 to 310, by 1 to 30 nucleotide substitutions; and c) complements to a) and b); said at least 20 contiguous nucleotides include the one or more nucleotides at position 60 of a) or b); and the one or more nucleotides at position 60 of said nucleotide sequences being selected from the two alternative forms of the allele to be determined.

DETAILED DESCRIPTION OF THE INVENTION

Unless specifically defined herein, all technical and scientific terms used have the same meaning as commonly understood by a skilled artisan in the fields of genetics, biochemistry, and molecular biology.

All methods and materials similar or equivalent to those described herein can be used in the practice or testing of the present invention, with suitable methods and materials being described herein. All publications, patent applications, patents, and other references mentioned herein are incorporated by reference in their entirety. In case of conflict, the present specification, including definitions, will prevail.

Where a numerical limit or range is stated herein, the endpoints are included. Also, all values and sub ranges within a numerical limit or range are specifically included as if explicitly written out.

Polymorphisms of the Invention

As used herein, a “polymorphism” is a variation in a genomic sequence. In particular, a polymorphism is an allelic variant that is generally found between individuals of a population. The polymorphism may be a single nucleotide difference present at a locus, or may be an insertion or deletion of one or a few nucleotides at a position of a gene.

As used herein, a “single nucleotide polymorphism” or “SNP” refers to a single base (nucleotide) polymorphism in a DNA sequence among individuals in a population. As such, a single nucleotide polymorphism is characterized by the presence in a population of one or two, three or four nucleotides (i.e. adenine, cytosine, guanine or thymine), typically less than all four nucleotides, at a particular locus in a genome.

As used herein, “polymorphic sequence” refers to a nucleotide sequence including a polymorphic site,

As used herein, a “polymorphic site” is the locus or position within a given sequence at which divergence occurs. Preferred polymorphic sites have at least two alleles, each occurring at frequency greater than 1%, such as greater than 5%. Those skilled in the art will recognize that nucleic acid molecules may be double-stranded molecules and that reference to a particular site on one strand refers, as well, to the corresponding site on a complementary strand. In defining a polymorphic site or allele reference to an adenine, a thymine, a cytosine, or a guanine at a particular site on one strand of a nucleic acid molecule also defines the thymine, adenine, guanine, or cytosine (respectively) at the corresponding site on a complementary strand of the nucleic acid.

The present inventors have identified quantitative trait locus (QTL) responsible for at least some of the genetic variation in milk fatty acid composition in female milk-producing Norwegian Red cattle. More specifically, the present inventors have identified polymorphisms within the genome, more particularly on chromosome 1, 4, 5, 6, 10, 11, 12, 13, 15, 17, 19, 23, 26 and 27 of Norwegian Red cattle which are associated with altered milk fatty acid composition in female milk-producing Norwegian Red cattle. Specific details of polymorphisms of the invention are provided in table 1 and table 2 below. The respective nucleotide sequences including the polymorphism at position 60 are shown in Table 2.

The polymorphism of the present invention can be present in either of two forms, i.e., the polymorphisms have a total of two alleles.

For the polymorphisms influencing only one trait (e.g. P #1), one allele can be characterized as being a “fat allele” and the other can be characterized as being a “non-fat allele”. A “fat allele” is associated with an increase in the amount of the fatty acid to which it relates while a “non-fat allele” is associated with a decrease in the amount of the fatty acid to which it relates, i.e. a “fat allele” for C18:1 is associated with an increase in the amount of C18:1 while a “non-fat allele” for C18:1 is associated with a decrease in the amount of C18:1. Thus, a female milk-producing cattle having a “fat allele” at the position of a polymorphism detailed herein provides milk with increased amount of the fatty acid to which the “fat allele” relates while a female milk-producing cattle having a “non-fat allele” at the position of a polymorphism detailed herein provides milk with decreased amount of the fatty acid to which the “fat allele” relates.

For the polymorphisms influencing more than one trait, one polymorphism allele may actually represent a “fat allele” for some of the traits and “non-fat allele” for the others. In order to clarify this even further, reference is made to P #15 where an adenine at the position of the polymorphic site is a “fat allele” for C4:0 and C6:0 while being a “non-fat allele” for CLA. Thus, a female milk-producing cattle having an adenine at the position of the polymorphic site of P #15 provides milk with increased amounts of C4:0 and C6:0 while the amount of CLA is decreased. On the other hand, a female milk-producing cattle having a guanine at the position of the polymorphic site of P #15 provides milk with decreased amounts of C4:0 and C6:0 while the amount of CLA is increased.

Since some of the polymorphisms according to the present invention influence only one trait while others influence more than one trait, the term “a polymorphism allele” is herein meant to refer to one of the two alternative forms of the polymorphism. Said in other words, P #15 has a total of two polymorphism alleles (A/G), i.e. there may be an adenine at the polymorphic site or a guanine at the polymorphic site. An adenine at the polymorphic site represents one polymorphism allele while a guanine at the polymorphic site represents the other polymorphism allele.

Nearly all mammals, including non-human mammals such as cattle, in particular Norwegian Red cattle, are diploid organisms and thus possess at least one copy of the polymorphisms of the invention.

As demonstrated herein, if at least one allele of a polymorphism is the respective “fat-allele” for a specific trait; then a female milk-producing cattle will be able to provide milk with increased content of the trait as compared to a female milk-producing cattle where both alleles are “non-fat allele” for the same trait (homozygous). It would be expected that milk from a female milk-producing cattle being homozygous for a “fat-allele” for a specific trait will contain higher amounts of that trait as compared to milk from a female milk-producing cattle being heterozygous for the “fat-allele” for the same specific trait.

A polymorphism of the invention may be any of several polymorphisms indicative of altered milk fatty acid composition in female milk-producing cattle. Particularly, a polymorphism of the invention is a polymorphism located on chromosome 1, 4, 5, 6, 10, 11, 12, 13, 15, 17, 19, 23, 26 and/or 27 of a cattle, i.e. a polymorphism found to be located on chromosome 1, 4, 5, 6, 10, 11, 12, 13, 15, 17, 19, 23, 26 and/or 27 on the basis of genetic linkage analysis, Fluorescence in situ Hybridization (FISH) or any other method that assigns DNA polymorphisms to their respective chromosomes.

As used herein, “genetic linkage analysis” refers to a statistical procedure where genotype data, coming from sets of animals comprising parents and their offspring, are investigated in order to test for the presence of genetic linkage between polymorphisms. Genetic linkage analysis can be used in order to assign polymorphisms to chromosomes, provided that the analysis incorporates polymorphisms that have already been assigned to chromosome using e.g.

Fluorescence In Situ Hybridiation.

As used herein “Fluorescence In Situ Hybridiation” or “FISH” refers to a technique that detect the presence or absence of specific DNA sequences on chromosomes. FISH can be used in order to assign known DNA polymorphisms to chromosomes.

As used herein, “genetic linkage” refers to the tendency of polymorphisms that are located close to each other on a chromosome to be inherited together during meiosis. Thus, polymorphisms located close to each other on the same chromosome are said to be genetically linked. Alleles at two such genetically linked loci are co-inherited (from parents to offspring) more often than they are not. Assume, for example, two polymorphisms; polymorphism A having alleles A1 and A2, and polymorphism B having alleles B1 and B2. Assume further that a given cattle carries all of the alleles A1, A2, B1, and B2 (in other words, this cattle is heterozygous at both marker and marker B). If alleles A1 and B1 are, in this particular cattle, located on the same chromosome copy, then alleles A1 and B1 are co-inherited, to the offspring of the cattle, more often than not.

The unit “centiMorgan” is a unit of measurement, used to describe genetic distances, where genetic distance is a measure of the extent to which two polymorphisms are genetically linked.

A polymorphism of the invention may be any polymorphism, including single nucleotide polymorphism, which is in strong linkage disequilibrium (LD) with a polymorphism selected from the group consisting of P #1 to P #916. Here, two polymorphisms are defined to be in strong LD if the square of the correlation coefficient between the two loci (r2, the most commonly used measure of LD) is equal to or larger than 0.7 such as equal to or larger than 0.75. A person who is skilled in the art will know how to estimate r2, as well as what data material is required for this estimation.

Linkage disequilibrium (LD) or, more precisely, gametic phase linkage disequilibrium is used in order to describe the co-inheritance of alleles at genetically linked polymorphisms, at the population level. Assume, for example, two polymorphisms located on the same chromosome; polymorphism A having alleles A1 and A2, and polymorphism B having alleles B1 and B2. All copies of the chromosome in question will harbor a combination of alleles at the two loci (i.e. a haplotype), and there are four possible haplotypes: A1-B1, A1-B2, A2-B1, and A2-B2. The two loci are in said to be LD with each other if the number of A1-B1 and A2-B2 haplotypes within the population are significantly larger or significantly smaller than the number of A1-B2 and A2-B1 haplotypes.

A polymorphism of the invention may be at least one of the polymorphisms listed in Table 1. Therefore, according to certain embodiments, the at least one polymorphism of the invention is selected from the polymorphisms listed in Table 1. Each of the polymorphisms listed in Table 1 is contemplated as being disclosed individually as part of the present invention.

TABLE 1 Polymorphisms indicative of altered milk fatty acid composition. P# is the number of the polymorphism according to the present invention. Trait refers to one or more fatty acid that is under the influence of the polymorphism in question. C4:0 is butyric acid, C6:0 is caproic acid, C8:0 is octanoic acid, C10:0 is decanoic acid, C12:0 is dodecanoic acid, C14:0 is tetradecanoic acid, C14:1cis-9 is myristoleic acid, C16:0 is hexadecanoic acid, C18:1 is Oleic acid, C18:1cis-9, C18:1cis-10, C18:1cis-11 and C18:1trans-9 are different isomers of Oleic acid. CLA is conjugated linoleic acid, DHA is docosahexaenoic acid, DNS represents de novo- synthesized acids (i.e., C6:0 to C16:0), MUFA is monounsaturated acids, NEFA are free fatty acids, SAT are saturated fatty acids. BTA# is the chromosome to which the polymorphism is positioned. The Ref# is the ID number of the polymorphism from the Single Nucleotide Polymorphism database. Position (bp) is the chromosome position from the UMD 3.1 assembly (NCBI assembly accession GCA_000003055.4). Those skilled in the art may easily identify the reference sequence and the position of the polymorphism within the NCBI (National Center for Biotechnology Information) Single Nucleotide Polymorphism Database. A = Adenine, G = Guanine; C = Cytosine, T = Thymine. “Fat allele” indicates the allele that is associated with an increase in the amount of the respective trait. “Non-Fat allele” indicates the allele that is associated with a decrease in the amount of the respective trait. The P# and the SEQIDNO are identical. P#/ Position Non-fat SEQIDNO Trait BTA # Ref # (bp) Fat allele allele   1 C8:0  1 rs29027221 126338729 A C C6:0 A C   2 DHA  1 rs41639338 126596653 A C   3 DNS  1 rs29021652 131979848 A G C12:0 A G C10:0 A G   4 CLA  4 rs41650703  48649499 A T   5 DHA  4 rs41612156  49857470 A G   6 CLA  5 rs41611305  91471989 T C SAT C T   7 C18:1trans-9  6 rs29024684  87396306 C A   8 C10:0 10 rs43707537  36369609 A G DNS A G   9 DNS 10 rs41623983  38738818 T A C14:0 A T C12:0 A T C10:0 A T  10 DNS 10 rs41623991  38968764 G A C8:0 G A C14:0 G A C12:0 G A C10:0 G A  11 C8:0 10 rs43707029  40424349 G A  12 C8:0 10 s43707539  43031877 G A C6:0 G A  13 C4:0 10 rs41568266  46642818 G A  14 C18:1cis-11 12 s41569014  88316926 C T  15 C4:0 13 rs29012218  55409520 A G C6:0 A G CLA G A  16 DNS 13 rs41631605  64500844 G A C8:0 G A C6:0 G A C10:0 G A C12:0 G A  17 DNS 13 rs29018443  64841951 C T C8:0 C T C6:0 C T C14:0 C T C12:0 C T C10:0 C T  18 DNS 13 rs41631563  66080035 C A C8:0 C A C14:0 C A C12:0 C A C10:0 C A  19 C10:0 15 s41582050  28098734 T C C12:0 T C C14:0 T C C18:1cis-9 C T C8:0 T C DNS T C  20 C12:0 15 rs41622342  64373612 G A C10:0 A G  21 C4:0 17 rs41637576  40693717 A G  22 C4:0 17 rs41637616  43463045 A G  23 C4:0 17 rs41637627  45145609 A C  24 C6:0 17 rs41636968  45302499 C T C4:0 C T  25 C4:0 17 rs41585556  45632698 C A  26 C4:0 17 rs41638773  47179691 G C  27 C4:0 17 rs41633197  47684549 A G  28 C4:0 17 rs41666579  47995988 A G  29 C4:0 17 rs41638780  49227724 A G  30 C4:0 17 rs41661878  51024797 G A  31 C4:0 17 rs41660449  53592758 G T  32 C4:0 17 rs41660450  53620065 C A  33 C16:0 17 s41630100  59778912 G A  34 SAT 17 rs41576270  61082159 A G MUFA G A C18:1cis-9 G A C14:0 A G  35 SAT 17 rs41634411  72384103 A G  36 NEFA 23 rs29019650  11907305 A C  37 C18:1cis-11 23 rs41617401  45507722 C A  38 SAT 26 rs41664843  27325539 T A C18:1cis-9 A T  39 SAT 26 rs41636621  28096889 C G MUFA G C C18:1cis-9 G C  40 C8:0 13 rs42476347  36576754 C T  41 C6:0 13 rs41577018  36579808 G T C8:0 G T  42 C8:0 13 rs29016293  36591954 T C  43 C8:0 13 rs109346582  39102096 T C  44 C8:0 13 rs43259281  39542292 T G DNS T G  45 C8:0 13 rs135689087  40632008 T C  46 C4:0 13 rs43434744  46062881 C T  47 C4:0 13 rs41696754  55421364 C T  48 C8:0 13 rs41698815  58523914 G A  49 DNS 13 rs110795124  59579696 A G C8:0 A G C12:0 A G C10:0 A G  50 C12:0 13 rs41701362  60112222 A C C10:0 A C  51 C10:0 13 rs133849041  60507659 G T C12:0 G T C8:0 G T DNS G T  52 C12:0 13 rs41705197  60515732 G T  53 C12:0 13 rs135049699  60521218 A C  54 C4:0 13 rs132915254  60527253 G A  55 C4:0 13 rs41699542  60570356 G A  56 C10:0 13 rs109785720  60627246 C T C8:0 C T DNS C T  57 DNS 13 rs109565416  60628472 G A C8:0 G A C10:0 G A  58 C10:0 13 rs41576886  60643827 C T C8:0 C T DNS C T  59 DNS 13 rs132981660  60688808 A C C8:0 A C C10:0 A C  60 C10:0 13 rs41703753  60691132 C T C8:0 C T DNS C T  61 C12:0 13 rs110362163  60695568 A G C10:0 A G  62 C12:0 13 rs133399057  60873458 G A C10:0 G A  63 C8:0 13 rs109001485  61902355 A G C6:0 A G  64 C10:0 13 rs109396998  61984979 C T C12:0 C T C6:0 C T C8:0 C T DNS C T  65 C8:0 13 rs136665696  62065597 C T DNS C T  66 DNS 13 rs109446607  62067270 A G C8:0 A G  67 C12:0 13 rs109256322  62068335 A G  68 C8:0 13 rs132702901  62069070 C T DNS C T  69 DNS 13 rs109995538  62448949 G A C8:0 G A C6:0 G A C12:0 G A C10:0 G A C14:0 G A  70 C10:0 13 rs110285330  62450667 T G C12:0 T G C6:0 T G C8:0 T G DNS T G C14:0 T G  71 DNS 13 rs110309401  62527818 A G C8:0 A G C6:0 A G C12:0 A G C10:0 A G  72 DNS 13 rs41706412  62528401 A C C8:0 A C C12:0 A C C10:0 A C  73 C8:0 13 rs43206444  62553264 C T DNS C T  74 DNS 13 rs41707249  62556854 G A C8:0 G A C6:0 G A C12:0 G A C10:0 G A  75 C6:0 13 rs134395454  62719766 T C C8:0 T C DNS T C  76 DNS 13 rs136727738  62727770 A G C8:0 A G C6:0 A G C10:0 A G  77 C10:0 13 rs41700824  62836175 C T C6:0 C T C8:0 C T DNS C T  78 DNS 13 rs41701735  62858269 A G C8:0 A G C6:0 A G C10:0 A G  79 C6:0 13 rs136662836  62885520 C T C8:0 C T  80 C8:0 13 rs110784592  62916334 A G C10:0 A G  81 C8:0 13 rs109587232  62925849 A G C10:0 A G  82 C10:0 13 rs110489811  62928756 T C C8:0 T C  83 C10:0 13 rs109862645  62933067 G T C12:0 G T C6:0 G T C8:0 G T DNS G T C14:0 G T  84 C10:0 13 rs109018242  62942668 T C C8:0 T C  85 DNS 13 rs133076301  62944250 G A C8:0 G A C6:0 G A C12:0 G A C10:0 G A C14:0 G A  86 C10:0 13 rs109518939  62947465 C T C12:0 C T C6:0 C T C8:0 C T DNS C T  87 DNS 13 rs110743763  62950126 A G C8:0 A G C6:0 A G C12:0 A G C10:0 A G  88 C10:0 13 rs41602440  62951257 T C C8:0 T C  89 C10:0 13 rs110608478  62953893 G T C12:0 G T C6:0 G T C8:0 G T DNS G T  90 C10:0 13 rs110813518  62954588 T G C12:0 T G C6:0 T G C8:0 T G DNS T G  91 C10:0 13 rs110767129  62955647 C T C12:0 C T C6:0 C T C8:0 C T DNS C T  92 DNS 13 rs110671382  62956547 A G C8:0 A G C6:0 A G C12:0 A G C10:0 A G  93 C10:0 13 rs108989331  62960536 T C C12:0 T C C6:0 T C C8:0 T C DNS T C  94 C12:0 13 rs110858883  62967761 C A C10:0 C A  95 C10:0 13 rs109248916  62969467 T C C12:0 T C  96 C12:0 13 rs108958622  62971963 A G C10:0 A G  97 C8:0 13 rs41624061  62987632 A G C6:0 A G  98 C6:0 13 rs135592700  63079589 A G  99 C6:0 13 rs109116663  63085508 T G C8:0 T G 100 C6:0 13 rs109001474  63093719 C T C8:0 C T 101 C8:0 13 rs110684557  63096370 G A C6:0 G A 102 C6:0 13 rs133997573  63109630 T C 103 C6:0 13 rs109083431  63115088 T C C8:0 T C 104 DNS 13 rs137086701  63142046 G A C8:0 G A C12:0 G A C10:0 G A 105 DNS 13 rs135714488  63144732 A G C8:0 A G C12:0 A G C10:0 A G 106 DNS 13 rs136873029  63146420 G A C8:0 G A C12:0 G A C10:0 G A 107 DNS 13 rs135016598  63146983 C A C8:0 C A C12:0 C A C10:0 C A 108 C10:0 13 rs133539257  63152787 T C C12:0 T C C8:0 T C DNS T C 109 C12:0 13 rs110667975  63157239 A G C10:0 A G 110 C12:0 13 rs110377320  63163288 A G 111 DNS 13 rs133516432  63173874 G A C8:0 G A C12:0 G A C10:0 G A 112 DNS 13 rs133227293  63235326 A G C8:0 A G C6:0 A G C12:0 A G C10:0 A G 113 C10:0 13 rs109626824  63236944 T C C12:0 T C C6:0 T C C8:0 T C DNS T C 114 DNS 13 rs135705002  63238798 A G C8:0 A G C6:0 A G C10:0 A G 115 DNS 13 rs41631546  63239686 A C C8:0 A C C6:0 A C C12:0 A C C10:0 A C 116 C8:0 13 rs41631542  63242901 A G C6:0 A G 117 DNS 13 rs137753247  63267570 G A C8:0 G A C6:0 G A C12:0 G A C10:0 G A C14:0 G A 118 C10:0 13 rs110620812  63428186 C T C12:0 C T C6:0 C T C8:0 C T DNS C T 119 C12:0 13 rs41616451  63715266 T C 120 C10:0 13 rs41707948  63843713 T C C12:0 T C C6:0 T C C8:0 T C DNS T C C14:0 T C 121 DNS 13 rs41707954  63848241 A G C8:0 A G C6:0 A G C12:0 A G C10:0 A G 122 C12:0 13 rs136064116  64028977 C T 123 C6:0 13 rs134716771  64150567 T C C8:0 T C 124 C6:0 13 rs134107495  64220819 C T C8:0 C T 125 C8:0 13 rs137438204  64226872 A G C6:0 A G 126 C8:0 13 rs132924857  64228423 A G C6:0 A G 127 C10:0 13 rs134956071  64349171 C T C6:0 C T C8:0 C T DNS C T C12:0 C T C14:0 C T 128 DNS 13 rs132687845  64354283 G A C8:0 G A C6:0 G A C12:0 G A C10:0 G A C14:0 G A 129 C8:0 13 rs135163820  64366788 A G C6:0 A G 130 C8:0 13 rs134080061  64398138 G A C6:0 G A 131 C8:0 13 rs29014977  64399733 T C C6:0 T C 132 C10:0 13 rs137134199  64411593 C T C6:0 C T C8:0 C T DNS C T C12:0 C T C14:0 C T 133 C10:0 13 rs109718644  64429162 C T C6:0 C T C8:0 C T DNS C T C12:0 C T C14:0 C T 134 C8:0 13 rs109390067  64432139 A G C6:0 A G 135 C8:0 13 rs136344221  64453214 G A C6:0 G A 136 DNS 13 rs110904633  64478327 A G C8:0 A G C10:0 A G 137 DNS 13 rs109739218  64480379 G A C8:0 G A C10:0 G A 138 DNS 13 rs136096188  64496757 G A C8:0 G A C6:0 G A C12:0 G A C10:0 G A 139 C10:0 13 rs43771381  64589486 T C C12:0 T C C6:0 T C C8:0 T C DNS T C C14:0 T C 140 DNS 13 rs41700748  64621429 G A C8:0 G A C6:0 G A C10:0 G A 141 C10:0 13 rs41700740  64650276 T C C12:0 T C C6:0 T C C8:0 T C DNS T C C14:0 T C C18:1cis-9 C T 142 DNS 13 rs43717470  64795019 G A C8:0 G A C12:0 G A C10:0 G A 143 DNS 13 rs43717461  64804947 C A C8:0 C A 144 C8:0 13 rs43717457  64831414 C T DNS C T 145 C8:0 13 rs43708452  64839762 T C DNS T C 146 DNS 13 rs43717453  64840460 C A C8:0 C A 147 DNS 13 rs43717439  64865042 G A C8:0 G A 148 DNS 13 rs43711970  65246092 A G C8:0 A G C6:0 A G C12:0 A G C10:0 A G C14:0 A G C18:1cis-9 G A 149 C10:0 13 rs110318473  65250364 T C C12:0 T C C14:0 T C C8:0 T C DNS T C 150 C12:0 13 rs109153523  65255565 G A C10:0 G A C14:0 G A C8:0 G A DNS G A 151 C10:0 13 rs133947598  65274414 C T C8:0 C T C12:0 C T C14:0 C T DNS C T 152 C8:0 13 rs43712870  65283149 G A C10:0 G A DNS G A 153 DNS 13 rs43712867  65285989 G A C8:0 G A C6:0 G A C12:0 G A C10:0 G A C14:0 G A C18:1cis-9 A G 154 C8:0 13 rs132985406  66563331 G A C6:0 G A 155 C6:0 13 rs132795765  66913824 C T C8:0 C T 156 C10:0 13 rs41700666  67463110 T C C6:0 T C C8:0 T C DNS T C 157 DNS 13 rs109518616  67464466 G A C8:0 G A C6:0 G A C10:0 G A 158 C10:0 13 rs110730675  67465157 T C C6:0 T C C8:0 T C DNS T C 159 DNS 13 rs109963351  67465890 G A C8:0 G A C6:0 G A C10:0 G A 160 DNS 13 rs110439451  67466746 A G C8:0 A G C6:0 A G C10:0 A G 161 DNS 13 rs109452111  67467905 G A C8:0 G A C6:0 G A C10:0 G A 162 C10:0 13 rs110654124  67468746 G T C6:0 G T C8:0 G T DNS G T 163 C10:0 13 rs41700654  67469211 C T C6:0 C T C8:0 C T DNS C T 164 DNS 13 rs41700644  67472330 A C C8:0 A C C6:0 A C C10:0 A C 165 DNS 13 rs41700641  67473098 A G C8:0 A G C6:0 A G C10:0 A G 166 DNS 13 rs109703974  67481524 G A C8:0 G A C6:0 G A C10:0 G A 167 C6:0 13 rs133268469  67697067 C T C8:0 C T DNS C T 168 C8:0 13 rs133086737  67932600 C A C6:0 C A 169 C8:0 13 rs133249272  68348045 G A 170 DNS 13 rs110626829  68349659 G A C8:0 G A 171 C8:0 13 rs109374207  68354415 C T 172 C8:0 13 rs109972468  68355260 T C 173 C8:0 13 rs134624250  68357436 G A 174 C8:0 13 rs109084883  68359199 T C 175 C8:0 13 rs134805509  68361570 C T 176 C8:0 13 rs109769171  68362587 A G 177 C8:0 13 rs133781741  68364357 T C DNS T C 178 C8:0 13 rs109399712  68370273 A G 179 C8:0 13 rs109404095  68375092 A G 180 C8:0 13 rs109590629  68376188 T C DNS T C 181 C8:0 13 rs110486144  68379681 T C DNS T C 182 C8:0 13 rs133277229  68399388 C T 183 C8:0 13 rs135144073  68419080 G T 184 C8:0 13 rs136438584  68422769 C T 185 C8:0 13 rs109162250  68425212 A C 186 C8:0 13 rs135924615  68433715 T C 187 C8:0 13 rs110112896  68435354 A G 188 C8:0 13 rs108943806  68436084 A G 189 C8:0 13 rs29027215  68436648 G A 190 C8:0 13 rs29027216  68437003 T C 191 C8:0 13 rs110456460  68437969 T C 192 C8:0 13 rs109738599  68443709 T C 193 C8:0 13 rs110322269  68444812 G A 194 C8:0 13 rs110931262  68446011 G A 195 C8:0 13 rs109583653  68448206 A C 196 C8:0 13 rs109860180  68448900 T C 197 C8:0 13 rs108999453  68449455 A C 198 C8:0 13 rs110200669  68452106 A G 199 C8:0 13 rs110695408  68462615 A G 200 C8:0 13 rs41631532  68468981 G A 201 C8:0 13 rs133762197  68473203 T C 202 C8:0 13 rs109215283  68487794 A G 203 C8:0 13 rs109548237  68492293 T G 204 C8:0 13 rs109802350  68503376 A G 205 C8:0 13 rs133387349  68505109 T C 206 C8:0 13 rs109762226  68506186 A G 207 C8:0 13 rs136130202  68521184 A G 208 C8:0 13 rs133603285  68521969 T C 209 C8:0 13 rs134928364  68523290 T G 210 C8:0 13 rs109812256  68524141 A G 211 C8:0 13 rs110322216  68524730 G A 212 C8:0 13 rs136586035  68905151 A G 213 C8:0 13 rs109707307  68906269 C T 214 C8:0 13 rs137634182  68911842 T C 215 C8:0 13 rs134363250  68920327 C T 216 C8:0 13 rs133185011  68925287 C T 217 C8:0 13 rs109620329  68931367 C T 218 C6:0 13 rs110840242  69070669 G T C8:0 G T 219 C12:0 13 rs109403285  73750114 C T 220 C6:0 13 rs109085782  77948974 G T C8:0 G T 221 C6:0 13 rs42924695  77962539 T C 222 C6:0 13 rs42924711  77971426 A G 223 C6:0 13 rs41713942  77991304 C A 224 C10:0 13 rs41700745  64639392 C T C12:0 C T C14:0 C T C6:0 C T C8:0 C T DNS C T 225 C10:0 13 rs41700742  64648620 A G C12:0 A G C14:0 A G C6:0 A G C8:0 A G DNS A G 226 C10:0 13 rs41700737  64655588 A G C12:0 A G C14:0 A G C6:0 A G C8:0 A G DNS A G 227 C8:0 13 rs41700736  64665113 A G 228 C8:0 13 rs109284257  64675657 T G 229 C8:0 13 rs43717522  64677620 T C 230 C8:0 13 rs43717523  64679414 G A 231 C8:0 13 rs43717484  64717871 A T DNS A T 232 DNS 13 rs41631583  65280649 G A 233 C18:1cis-9  5 rs136287575  93943798 C T 234 C18:1cis-9  5 rs110489943  94901838 C A 235 C18:1cis-9  5 rs136663774  94903186 G A 236 C18:1cis-9  5 rs133770935  94908043 C A 237 C18:1cis-9  5 rs135667197  94913073 C A 238 C18:1cis-9  5 rs109696313  94984140 T C 239 C18:1cis-9  5 rs137700249  95007471 C T 240 C18:1cis-9  5 rs134037603  95025828 A G 241 C16:0 11 rs109331017 102823112 T G 242 C18:1cis-9 11 rs135586826 103293363 G A C16:0 A G C4:0 A G 243 C4:0 11 rs110186753 103302351 T C C16:0 T C C18:1cis-9 C T C14:1cis-9 C T 244 C4:0 11 rs110143060 103304643 T C C16:0 T C C18:1cis-9 C T C14:1cis-9 C T 245 C18:1cis-9 11 rs109087963 103308330 A G C16:0 G A C4:0 G A C14:1cis-9 A G 246 C4:0 11 rs135786912 103317601 G T C16:0 G T C18:1cis-9 T G C14:1cis-9 T G 247 C16:0 11 rs136428773 103319019 C T C4:0 C T 248 C16:0 11 rs110755821 103321851 C T 249 C6:0 17 rs137785016  48355536 A G 250 C6:0 17 rs135583765  48361819 C T 251 C4:0 17 rs41572286  48976925 G A 252 C4:0 17 rs109188645  49580330 C T 253 C6:0 17 rs135427193  50117287 G T 254 C8:0 17 rs109783607  51076762 A G C6:0 A G 255 C6:0 17 rs109106552  51078591 C T 256 C6:0 17 rs109169489  51097333 T G 257 C6:0 17 rs137580316  51599696 T C 258 C6:0 17 rs110872295  51668957 C T C8:0 C T 259 C6:0 17 rs137014685  51682489 C T C8:0 C T 260 C6:0 17 rs136965059  51768322 A G 261 C4:0 17 rs110689162  52740162 C T 262 C4:0 17 rs109629120  52743106 C T 263 C4:0 17 rs110726640  52743970 G T 264 C4:0 17 rs109533435  52745714 C A 265 C4:0 17 rs110836032  52746731 C T 266 C4:0 17 rs109989624  52747491 G A 267 C6:0 17 rs137761118  52772547 G A C4:0 G A 268 C8:0 17 rs109371141  53866646 A G 269 C4:0 17 rs133978310  53946879 A G 270 C8:0 17 rs137653132  56174646 T C 271 C18:1cis-9 19 rs109672704  31379078 A G 272 C18:1cis-9 19 rs109327080  31382204 T C 273 C18:1cis-9 19 rs109555691  31391100 A G 274 C18:1cis-9 19 rs41908647  35648763 C A 275 C14:0 19 rs29017737  36822248 T C C18:1cis-9 C T 276 C12:0 19 rs134057897  36832507 C T C14:0 C T C18:1cis-9 T C 277 C18:1cis-9 19 rs109993655  36833660 A G 278 C18:1cis-9 19 rs17870773  36834825 C T 279 C14:0 19 rs110311467  37277118 C T 280 C14:0 19 rs133472242  37278241 C T C18:1cis-9 T C 281 C18:1cis-9 19 rs110273711  37281135 A C C14:0 C A 282 C18:1cis-9 19 rs41913837  37281739 A G 283 C18:1cis-9 19 rs133455441  37289888 C T 284 C14:0 19 rs136512659  37294490 C T 285 C8:0 19 rs41913893  37304511 C T C10:0 C T C12:0 C T C14:0 C T C18:1cis-9 T C 286 C8:0 19 rs136626835  37324253 T G C10:0 T G C12:0 T G C14:0 T G 287 C8:0 19 rs41913877  37326298 T C C10:0 T C C12:0 T C C14:0 T C 288 C8:0 19 rs41576366  37396572 T G C10:0 T G C12:0 T G C14:0 T G 289 C14:0 19 rs41922131  51307828 C T C18:1cis-9 T C 290 C18:1cis-9 19 rs108973837  51312108 G A C14:0 A G C12:0 A G 291 C14:0 19 rs41921159  51319695 T C C18:1cis-9 C T C12:0 T C 292 C18:1cis-9 19 rs41921164  51320976 G A C14:0 A G C12:0 A G 293 C14:0 19 rs41921166  51322878 T C C18:1cis-9 C T C12:0 T C 294 C14:0 19 rs41921170  51323848 G T C18:1cis-9 T G C12:0 G T 295 C18:1cis-9 19 rs41921171  51325151 G A C14:0 A G C12:0 A G 296 C18:1cis-9 19 rs41921177  51326750 G A C14:0 A G C12:0 A G 297 C10:0 19 rs136244801  51333432 T C C12:0 T C C14:0 T C C18:1cis-9 C T 298 C18:1cis-9 19 rs41921146  51341014 G A C14:0 A G C12:0 A G C10:0 A G 299 C18:1cis-9 19 rs41921143  51343311 G A C14:0 A G C12:0 A G C10:0 A G 300 C18:1cis-9 19 rs41921140  51349695 G A C14:0 A G C12:0 A G C10:0 A G 301 C18:1cis-9 19 rs41920007  51380689 C A C14:0 A C C12:0 A C C10:0 A C 302 C8:0 19 rs137372738  51386735 C T C10:0 C T C12:0 C T C14:0 C T C18:1cis-9 T C 303 C16:0 27 rs110519353  36155097 C T 304 C16:0 27 rs41585476  36208029 A G 305 C16:0 27 rs109248310  36258043 A G 306 C16:0 27 rs137660318  36259278 T C 307 C16:0 27 rs133436102  36260026 T C 308 C16:0 27 rs109632695  36263175 A G 309 C16:0 27 rs109528207  36263939 T C 310 C16:0 27 rs135357086  36265705 C T 311 C4:0 11 rs110270048 103291134 T C C16:0 T C C18:1cis-9 C T 312 C4:0 11 rs109333988 103291146 C G C16:0 C G C18:1cis-9 G C 313 C4:0 11 rs136445488 103291159 C T C18:1cis-9 T C 314 C4:0 11 rs110051628 103291319 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 315 C4:0 11 rs381584633 103291361 TA T C16:0 TA T C14:1cis-9 T TA C18:1cis-9 T TA 316 C4:0 11 rs384433424 103291484 GC G C16:0 GC G C14:1cis-9 G GC C18:1cis-9 G GC 317 C4:0 11 rs208736858 103291675 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 318 C4:0 11 rs110769099 103291679 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 319 C4:0 11 rs209171393 103291891 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 320 C4:0 11 rs210927678 103291906 A T C16:0 A T C14:1cis-9 T A C18:1cis-9 T A 321 C4:0 11 rs110531467 103291944 T G C16:0 T G C14:1cis-9 G T C18:1cis-9 G T 322 C4:0 11 rs209455741 103292014 T G C16:0 T G C14:1cis-9 G T C18:1cis-9 G T 323 C4:0 11 rs110837274 103292067 C A C16:0 C A C14:1cis-9 A C C18:1cis-9 A C 324 C4:0 11 rs383493080 103292127 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 325 C4:0 11 rs377820370 103292307 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 326 C4:0 11 rs382086188 103292320 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 327 C4:0 11 rs383398415 103292402 C A C16:0 C A C14:1cis-9 A C C18:1cis-9 A C 328 C4:0 11 rs378684690 103292448 G T C16:0 G T C14:1cis-9 T G C18:1cis-9 T G 329 C4:0 11 rs381316841 103292468 A T C16:0 A T C14:1cis-9 T A C18:1cis-9 T A 330 C4:0 11 rs384539253 103292523 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 331 C4:0 11 rs379221045 103292572 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 332 C4:0 11 rs381050299 103292575 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 333 C16:0 11 rs384126999 103292628 A C C18:1cis-9 C A 334 C4:0 11 rs383134813 103292677 C G C16:0 C G C14:1cis-9 G C C18:1cis-9 G C 335 C4:0 11 rs517746215 103292741 G C C16:0 G C C14:1cis-9 C G 336 C4:0 11 rs438581757 103292742 G A C16:0 G A C14:1cis-9 A G 337 C4:0 11 rs458709486 103292747 A C C16:0 A C C14:1cis-9 C A 338 C4:0 11 rs799698615 103292760 T C C16:0 T C C14:1cis-9 C T 339 C4:0 11 rs797673592 103292762 G T C16:0 G T C14:1cis-9 T G C18:1cis-9 T G 340 C4:0 11 rs379863485 103292781 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 341 C4:0 11 rs382950378 103292802 G T C16:0 G T 342 C4:0 11 rs385886579 103292803 A G C16:0 A G 343 C4:0 11 rs380505424 103292935 C T C16:0 C T C18:1cis-9 T C 344 C16:0 11 rs383532834 103292945 A G C18:1cis-9 G A 345 C18:1cis-9 11 rs385457481 103292970 A G 346 C4:0 11 rs383579476 103293198 G T C16:0 G T C14:1cis-9 T G C18:1cis-9 T G 347 C4:0 11 rs109971913 103293370 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 348 C4:0 11 rs109539834 103293458 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 349 C4:0 11 rs109209173 103293485 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 350 C4:0 11 rs209767544 103293584 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 351 C4:0 11 rs207729763 103293600 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 352 C4:0 11 rs109454381 103293623 A T C16:0 A T C14:1cis-9 T A C18:1cis-9 T A 353 C4:0 11 rs109026837 103293813 T C C16:0 T C C18:1cis-9 C T 354 C4:0 11 rs380721908 103293911 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 355 C4:0 11 rs110303032 103293921 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 356 C4:0 11 rs209767082 103293968 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 357 C4:0 11 rs109272848 103294139 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 358 C4:0 11 rs455411619 103294245 G GGT C16:0 G GGT C14:1cis-9 GGT G C18:1cis-9 GGT G 359 C4:0 11 rs383822350 103294259 G T C16:0 G T C14:1cis-9 T G C18:1cis-9 T G 360 C4:0 11 rs377841524 103294366 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 361 C4:0 11 rs109733270 103294403 G C C16:0 G C C14:1cis-9 C G C18:1cis-9 C G 362 C4:0 11 rs109531047 103294429 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 363 C4:0 11 rs110076614 103294434 A T C16:0 A T C14:1cis-9 T A C18:1cis-9 T A 364 C4:0 11 rs110372120 103294605 A T C16:0 A T C18:1cis-9 T A 365 C4:0 11 rs110063984 103294607 G T C16:0 G T C18:1cis-9 T G 366 C4:0 11 rs110388337 103294682 C A C16:0 C A C14:1cis-9 A C C18:1cis-9 A C 367 C4:0 11 rs207607053 103294772 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 368 C4:0 11 rs109361146 103294818 T G C16:0 T G C14:1cis-9 G T C18:1cis-9 G T 369 C4:0 11 rs110377516 103294930 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 370 C4:0 11 rs110143023 103295050 C G C16:0 C G C14:1cis-9 G C C18:1cis-9 G C 371 C4:0 11 rs109286526 103295211 G C C16:0 G C C14:1cis-9 C G C18:1cis-9 C G 372 C4:0 11 rs208026057 103295526 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 373 C4:0 11 rs110512392 103295907 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 374 C4:0 11 rs381989107 103296192 C A C16:0 C A C14:1cis-9 A C C18:1cis-9 A C 375 C4:0 11 rs385106761 103296261 C G C16:0 C G C14:1cis-9 G C C18:1cis-9 G C 376 C4:0 11 rs379692402 103296321 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 377 C4:0 11 rs383037149 103296337 G C C16:0 G C C14:1cis-9 C G C18:1cis-9 C G 378 C4:0 11 rs385328050 103296383 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 379 C4:0 11 rs380406578 103296877 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 380 C4:0 11 rs383436530 103296920 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 381 C4:0 11 rs109628546 103297341 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 382 C4:0 11 rs208280659 103297793 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 383 C4:0 11 rs109817665 103297968 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 384 C4:0 11 rs211084229 103298098 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 385 C4:0 11 rs208564616 103298237 C G C16:0 C G C14:1cis-9 G C C18:1cis-9 G C 386 C4:0 11 rs211132416 103298241 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 387 C4:0 11 rs109990597 103298254 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 388 C4:0 11 rs110281106 103298257 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 389 C4:0 11 rs109955364 103298374 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 390 C4:0 11 rs109046993 103298385 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 391 C4:0 11 rs109166248 103298431 A T C16:0 A T C14:1cis-9 T A C18:1cis-9 T A 392 C4:0 11 rs110661775 103298458 T G C16:0 T G C14:1cis-9 G T C18:1cis-9 G T 393 C4:0 11 rs110276402 103298698 T A C16:0 T A C18:1cis-9 A T 394 C4:0 11 rs109008083 103298745 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 395 C4:0 11 rs110703191 103299004 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 396 C4:0 11 rs209121343 103299184 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 397 C4:0 11 rs110563549 103299272 G A C16:0 G A C18:1cis-9 A G 398 C4:0 11 rs109554394 103299275 G C C16:0 G C C14:1cis-9 C G C18:1cis-9 C G 399 C4:0 11 rs110860386 103299387 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 400 C4:0 11 rs110802466 103299453 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 401 C4:0 11 rs110933198 103299655 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 402 C4:0 11 rs109688459 103299687 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 403 C4:0 11 rs110659098 103299696 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 404 C4:0 11 rs109733140 103299747 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 405 C4:0 11 rs109509741 103299801 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 406 C4:0 11 rs461776512 103299807 TG T C16:0 TG T C14:1cis-9 T TG C18:1cis-9 T TG 407 C4:0 11 rs110710904 103299858 C G C16:0 C G C14:1cis-9 G C C18:1cis-9 G C 408 C4:0 11 rs209693172 103299916 C G C16:0 C G C14:1cis-9 G C C18:1cis-9 G C 409 C4:0 11 rs211534131 103299937 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 410 C4:0 11 rs208570651 103299941 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 411 C4:0 11 rs110387275 103300020 T C C16:0 T C C18:1cis-9 C T 412 C4:0 11 rs109843613 103300067 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 413 C4:0 11 rs110750786 103300078 G T C16:0 G T C14:1cis-9 T G C18:1cis-9 T G 414 C4:0 11 rs110888023 103300244 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 415 C4:0 11 rs110053249 103300324 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 416 C4:0 11 rs109982707 103300548 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 417 C4:0 11 rs109105837 103300608 C A C16:0 C A C14:1cis-9 A C C18:1cis-9 A C 418 C4:0 11 rs110024463 103300672 G C C16:0 G C C14:1cis-9 C G C18:1cis-9 C G 419 C4:0 11 rs109837926 103300697 A C C16:0 A C C14:1cis-9 C A C18:1cis-9 C A 420 C4:0 11 rs110920335 103300718 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 421 C4:0 11 rs110335984 103300719 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 422 C4:0 11 rs109897196 103300725 G C C16:0 G C C14:1cis-9 C G C18:1cis-9 C G 423 C4:0 11 rs110766819 103300899 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 424 C4:0 11 rs41255675 103301002 C G C16:0 C G C14:1cis-9 G C C18:1cis-9 G C 425 C4:0 11 rs41255676 103301030 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 426 C4:0 11 rs41255677 103301063 C A C16:0 C A C14:1cis-9 A C C18:1cis-9 A C 427 C4:0 11 rs41255678 103301202 G C C16:0 G C C14:1cis-9 C G C18:1cis-9 C G 428 C4:0 11 rs41255679 103301229 G C C16:0 G C C14:1cis-9 C G C18:1cis-9 C G 429 C4:0 11 rs41255682 103301443 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 430 C4:0 11 rs41255683 103301455 C G C16:0 C G C14:1cis-9 G C C18:1cis-9 G C 431 C4:0 11 rs41255684 103301561 C G C16:0 C G C14:1cis-9 G C C18:1cis-9 G C 432 C4:0 11 rs41255685 103301690 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 433 C4:0 11 rs41255686 103301694 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 434 C4:0 11 rs41255687 103301736 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 435 C4:0 11 rs109116595 103301757 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 436 C4:0 11 rs110788821 103301805 G C C16:0 G C C14:1cis-9 C G C18:1cis-9 C G 437 C4:0 11 rs109907194 103301982 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 438 C4:0 11 rs110874271 103302129 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 439 C4:0 11 rs109947864 103302272 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 440 C4:0 11 rs109755032 103302429 G C C16:0 G C C14:1cis-9 C G C18:1cis-9 C G 441 C4:0 11 rs383883089 103302617 C CA C16:0 C CA C14:1cis-9 CA C C18:1cis-9 CA C 442 C4:0 11 rs110537205 103302766 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 443 C4:0 11 rs43691047 103303242 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 444 C4:0 11 rs43691048 103303327 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 445 C4:0 11 rs43691049 103303343 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 446 C4:0 11 rs110066229 103303475 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 447 C4:0 11 rs110886675 103303619 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 448 C4:0 11 rs110205058 103303620 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 449 C4:0 11 rs110962910 103303700 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 450 C4:0 11 rs109498796 103303701 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 451 C4:0 11 rs109863113 103303792 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 452 C4:0 11 rs382320425 103303839 T TA C16:0 T TA C14:1cis-9 TA T C18:1cis-9 TA T 453 C4:0 11 rs211153297 103304094 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 454 C4:0 11 rs208613318 103304197 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 455 C4:0 11 rs210362322 103304235 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 456 C4:0 11 rs110941132 103304468 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 457 C4:0 11 rs110684335 103304476 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 458 C4:0 11 rs110992345 103304509 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 459 C4:0 11 rs110688769 103304510 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 460 C4:0 11 rs109890044 103304593 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 461 C4:0 11 rs109990218 103304656 A T C16:0 A T C14:1cis-9 T A C18:1cis-9 T A 462 C4:0 11 rs110641366 103304668 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 463 C4:0 11 rs109625649 103304757 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 464 C4:0 11 rs137003236 103304944 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 465 C4:0 11 rs207607418 103305230 T G C16:0 T G C14:1cis-9 G T C18:1cis-9 G T 466 C4:0 11 rs109021803 103305742 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 467 C4:0 11 rs110480949 103305744 C T C16:0 C T C14:1cis-9 T C C18:1cis-9 T C 468 C4:0 11 rs110405716 103306167 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 469 C4:0 11 rs383482709 103307124 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 470 C4:0 11 rs110935748 103307330 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 471 C4:0 11 rs110328877 103308459 A G C16:0 A G C14:1cis-9 G A C18:1cis-9 G A 472 C4:0 11 rs110351291 103312638 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 473 C4:0 11 rs210855396 103313920 C A C16:0 C A C14:1cis-9 A C C18:1cis-9 A C 474 C4:0 11 rs109880410 103315024 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 475 C4:0 11 rs133607453 103318190 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 476 C4:0 11 rs110513870 103321477 C T 477 C4:0 11 rs210419726 103321929 T G C16:0 T G C14:1cis-9 G T C18:1cis-9 G T 478 C4:0 11 rs470960381 103321961 T TA C16:0 T TA C14:1cis-9 TA T C18:1cis-9 TA T 479 C4:0 11 rs109891490 103322072 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 480 C4:0 11 rs209097885 103322398 G A C16:0 G A C14:1cis-9 A G C18:1cis-9 A G 481 C4:0 11 rs110788899 103322890 T C C16:0 T C C14:1cis-9 C T C18:1cis-9 C T 482 C4:0 11 rs465985450 103323672 A AG 483 C14:0 13  63086920 A C 484 C14:0 13  63086927 G A C18:1cis-9 A G 485 C14:0 13  63086938 G A C18:1cis-9 A G 486 C14:0 13  63086943 C T C18:1cis-9 T C 487 C12:0 13  63086946 G A C14:0 G A C18:1cis-9 A G 488 C12:0 13  63086958 T C C14:0 T C C18:1cis-9 C T 489 C12:0 13 rs469941426  63086971 C T C14:0 C T C18:1cis-9 T C 490 C10:0 13  63086974 C A C12:0 C A C14:0 C A C18:1cis-9 A C 491 C10:0 13  63086976 C T C12:0 C T C14:0 C T C18:1cis-9 T C 492 C10:0 13  63086979 T A C12:0 T A C14:0 T A C18:1cis-9 A T 493 C10:0 13  63086983 C A C12:0 C A C14:0 C A C18:1cis-9 A C 494 C10:0 13  63086994 T A C12:0 T A C14:0 T A C18:1cis-9 A T 495 C6:0 13 rs450388115  63095347 C T C8:0 C T C12:0 C T 496 C8:0 13 rs460746052  63140316 A C 497 C12:0 13 rs134471111  63228180 A G C14:0 A G C18:1cis-9 G A 498 C8:0 13 rs384099886  63266009 T C 499 C6:0 13 rs43711793  63270097 A T C8:0 A T 500 C8:0 13 rs384853631  63302895 C T 501 C6:0 13 rs466662937  63507251 G A C8:0 G A C10:0 G A C12:0 G A C14:0 G A 502 C8:0 13 rs476559105  63509737 C G C10:0 C G C12:0 C G C14:0 C G 503 C6:0 13  63521011 G A C8:0 G A C10:0 G A C12:0 G A C14:0 G A 504 C6:0 13  63524193 T C C8:0 T C C10:0 T C C12:0 T C C14:0 T C 505 C6:0 13  63525254 G GA C8:0 G GA C10:0 G GA C12:0 G GA C14:0 G GA 506 C6:0 13 rs440895334  63525614 G A C8:0 G A C10:0 G A C12:0 G A C14:0 G A 507 C6:0 13 rs446522735  63544624 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 508 C6:0 13 rs379551233  63572279 G A C8:0 G A C10:0 G A C12:0 G A C14:0 G A 509 C6:0 13 rs382779775  63572280 T G C8:0 T G C10:0 T G C12:0 T G C14:0 T G 510 C6:0 13 rs380845667  63617034 G A C8:0 G A C10:0 G A C12:0 G A C14:0 G A 511 C6:0 13 rs471902607  63660381 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 512 C6:0 13 rs385104196  63728651 G A C8:0 G A C10:0 G A C12:0 G A C14:0 G A 513 C6:0 13 rs378811160  63731561 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 514 C6:0 13 rs378303170  63734337 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 515 C8:0 13 rs454344378  63734389 A G C12:0 A G 516 C8:0 13  63735056 GAGATGAG GAGATGA TGCAATTG GTGCAAT TGCA TGTGCG 517 C6:0 13 rs379649986  63741818 T C C8:0 T C C10:0 T C C12:0 T C C14:0 T C 518 C6:0 13 rs380223633  63742135 C A C8:0 C A C10:0 C A C12:0 C A C14:0 C A 519 C6:0 13 rs480865010  63742388 T G C8:0 T G C10:0 T G C12:0 T G C14:0 T G 520 C6:0 13 rs380980005  63743062 T G C8:0 T G C10:0 T G C12:0 T G C14:0 T G 521 C6:0 13 rs473249925  63743159 G A C8:0 G A C10:0 G A C12:0 G A C14:0 G A 522 C6:0 13 rs441218700  63743195 C A C8:0 C A C10:0 C A C12:0 C A C14:0 C A 523 C6:0 13 rs383480158  63743346 T G C8:0 T G C10:0 T G C12:0 T G C14:0 T G 524 C6:0 13 rs377841389  63743596 G C C8:0 G C C10:0 G C C12:0 G C C14:0 G C 525 C6:0 13 rs381415308  63747026 T C C8:0 T C C10:0 T C C12:0 T C C14:0 T C 526 C6:0 13 rs380484412  63747747 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 527 C6:0 13 rs377908725  63753096 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 528 C6:0 13 rs464634573  63761735 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 529 C6:0 13 rs441127270  63765767 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 530 C6:0 13 rs720136600  63770658 G A C8:0 G A C10:0 G A C12:0 G A C14:0 G A 531 C6:0 13 rs719865499  63773948 G A C8:0 G A C10:0 G A C12:0 G A C14:0 G A 532 C6:0 13 rs475450155  63792022 G A C8:0 G A C10:0 G A C12:0 G A C14:0 G A 533 C6:0 13 rs384902852  63792952 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 534 C6:0 13 rs382787142  63804097 G A C8:0 G A C10:0 G A C12:0 G A C14:0 G A 535 C6:0 13 rs467176730  63808494 G T C8:0 G T C10:0 G T C12:0 G T C14:0 G T 536 C6:0 13 rs378623574  63810159 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 537 C6:0 13 rs518047916  63816410 A T C8:0 A T C10:0 A T C12:0 A T C14:0 A T 538 C6:0 13  63860287 C G C8:0 C G C10:0 C G C12:0 C G C14:0 C G 539 C6:0 13 rs380118486  63882786 G T C8:0 G T C10:0 G T C12:0 G T C14:0 G T 540 C12:0 13 rs386055644 63889282 T C 541 C6:0 13  63986107 G A C8:0 G A C10:0 G A C12:0 G A C14:0 G A 542 C6:0 13  64122383 G A C8:0 G A C10:0 G A C12:0 G A 543 C8:0 13 rs436218085  64233632 T TA C10:0 T TA C12:0 T TA C14:0 T TA C18:1cis-9 TA T 544 C6:0 13 rs380237156  64326275 G A C8:0 G A C10:0 G A C12:0 G A C14:0 G A 545 C6:0 13  64430137 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 546 C6:0 13  64437619 T G C8:0 T G C10:0 T G C12:0 T G C14:0 T G 547 C6:0 13 rs379219552  64459763 A G C8:0 A G C10:0 A G C12:0 A G C14:0 A G 548 C8:0 13 rs109108602  64493021 G T C14:0 G T 549 C8:0 13 rs109442789  64493180 C T C14:0 C T 550 C8:0 13 rs381918818  64493633 G T C14:0 G T 551 C8:0 13 rs457495420  64497075 C T C10:0 C T C12:0 C T C14:0 C T 552 C14:0 13 rs109417777  64498134 G T 553 C14:0 13 rs207527222  64501066 G C 554 C6:0 13 rs477403418  64507457 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 555 C6:0 13 rs461887762  64511038 CAGA C C8:0 CAGA C C10:0 CAGA C C12:0 CAGA C C14:0 CAGA C 556 C6:0 13 rs449972870  64513840 G A C8:0 G A C10:0 G A C12:0 G A C14:0 G A 557 C6:0 13 rs459399631  64516203 TTA T C8:0 TTA T C10:0 TTA T C12:0 TTA T C14:0 TTA T 558 C6:0 13 rs459530428  64519771 A AC C8:0 A AC C10:0 A AC C12:0 A AC C14:0 A AC 559 C6:0 13 rs449337366  64523547 C G C8:0 C G C10:0 C G C12:0 C G C14:0 C G 560 C6:0 13 rs381037433  64523817 G GA C8:0 G GA C10:0 G GA C12:0 G GA C14:0 G GA 561 C6:0 13 rs435926822  64523974 G A C8:0 G A C10:0 G A C12:0 G A C14:0 G A 562 C6:0 13 rs459756383  64526071 G A C8:0 G A C10:0 G A C12:0 G A C14:0 G A 563 C6:0 13 rs467272315  64527018 C G C8:0 C G C10:0 C G C12:0 C G C14:0 C G 564 C6:0 13 rs446495267  64529334 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 565 C6:0 13 rs720522852  64529994 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 566 C6:0 13 rs480211939  64544921 T G C8:0 T G C10:0 T G C12:0 T G C14:0 T G 567 C6:0 13 rs458143544  64550756 T C C8:0 T C C10:0 T C C12:0 T C C14:0 T C 568 C6:0 13  64555339 G C C8:0 G C C10:0 G C C12:0 G C C14:0 G C 569 C6:0 13 rs523108279  64568326 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 570 C6:0 13  64569790 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 571 C6:0 13 rs41700747  64632478 T A C8:0 T A C10:0 T A C12:0 T A C14:0 T A 572 C6:0 13 rs473665961  64641380 G A C8:0 G A C10:0 G A C12:0 G A C14:0 G A 573 C6:0 13 rs475365460  64641613 G A C8:0 G A C10:0 G A C12:0 G A C14:0 G A 574 C6:0 13 rs384960422  64642051 T C C8:0 T C C10:0 T C C12:0 T C C14:0 T C 575 C6:0 13 rs378971460  64642826 G C C8:0 G C C10:0 G C C12:0 G C C14:0 G C 576 C6:0 13 rs384124018  64644542 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 577 C6:0 13  64654792 TATAC T C8:0 TATAC T C10:0 TATAC T C12:0 TATAC T C14:0 TATAC T 578 C6:0 13 rs41700738  64655523 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 579 C6:0 13  64690602 A G C8:0 A G C10:0 A G C12:0 A G C14:0 A G 580 C6:0 13  64729354 C T C8:0 C T C10:0 C T C12:0 C T C14:0 C T 581 C6:0 13  64782240 C T C8:0 C T 582 C6:0 13  64837445 G A C8:0 G A 583 C6:0 13  64906333 C T C8:0 C T 584 C6:0 13  65032275 C T C8:0 C T C14:0 C T 585 C6:0 13  65186495 C G C8:0 C G C10:0 C G C12:0 C G C14:0 C G 586 C8:0 13 rs211165594  65200902 A G C10:0 A G C12:0 A G C14:0 A G 587 C14:0 13 rs43711986  65214101 G A 588 C12:0 13 rs110083815  65243590 G A C14:0 G A C18:1cis-9 A G 589 C10:0 13 rs109278546  65248121 C T C12:0 C T C14:0 C T C18:1cis-9 T C 590 C6:0 13  65296364 A G C8:0 A G C10:0 A G C12:0 A G C14:0 A G 591 C6:0 13 rs522985070  65310168 A T C8:0 A T C10:0 A T C12:0 A T C14:0 A T 592 C6:0 13  65321350 G T C8:0 G T C10:0 G T C12:0 G T C14:0 G T 593 C8:0 13  65351040 T G C10:0 T G C12:0 T G C14:0 T G 594 C8:0 13  65487713 C G C12:0 C G C14:0 C G 595 C4:0 17 rs210620686  52971285 C T C6:0 C T 596 C4:0 17 rs207997694  52971731 T C C6:0 T C 597 C4:0 17 rs211685274  52975212 G A C6:0 G A 598 C4:0 17 rs384356231  52981667 T C 599 C4:0 17 rs385196649  52983677 A G C6:0 A G 600 C4:0 17 rs383939492  52988005 T C C6:0 T C 601 C4:0 17 rs209715690  52993411 T C C6:0 T C 602 C4:0 17 rs378897148  52995059 T C C6:0 T C 603 C6:0 17  52998445 A G 604 C4:0 17 rs207984047  52999963 T A C6:0 T A 605 C4:0 17 rs41638794  53010785 A C C6:0 A C 606 C4:0 17 rs208784259  53021531 C T C6:0 C T 607 C4:0 17 rs379775146  53023240 C A C6:0 C A 608 C4:0 17 rs208914703  53025568 G A C6:0 G A 609 C6:0 17 rs465933786  53027601 T C 610 C6:0 17 rs436736287  53028054 A G 611 C4:0 17 rs382516208  53029882 G A C6:0 G A 612 C6:0 17  53032498 A C 613 C6:0 17  53033208 T C 614 C6:0 17 rs461037541  53034516 G A 615 C4:0 17 rs446350814  53038789 C T 616 C4:0 17 rs469684844  53041483 C A 617 C6:0 17 rs470804340  53043920 A G 618 C6:0 17 rs479802539  53049691 G A 619 C6:0 17 rs449032230  53051338 G A 620 C6:0 17 rs465071565  53052990 A G 621 C6:0 17 rs481844245  53053021 A C 622 C4:0 17 rs444541341  53053566 T A 623 C4:0 17 rs381799511  53054196 G A C6:0 G A 624 C4:0 17 rs378454875  53054197 G A C6:0 G A 625 C4:0 17  53058249 C T C6:0 C T 626 C6:0 17 rs435036894  53065665 T C 627 C4:0 17 rs521892164  53070436 T C C6:0 T C 628 C6:0 17  53071500 TACACACA T CACACACA CACACACA CACACAC C8:0 TACACACA T CACACACA CACACACA CACACAC C10:0 TACACACA T CACACACA CACACACA CACACAC 629 C4:0 17 rs384625792  53072209 C T C6:0 C T 630 C6:0 17 rs448501071  53072959 T C 631 C6:0 17 rs444137034  53073328 T C 632 C6:0 17 rs447613358  53073930 C T 633 C4:0 17 rs432216053  53074086 AAC A C6:0 AAC A 634 C4:0 17 rs452468649  53074119 A G C6:0 A G 635 C4:0 17 rs437826696  53074186 A G C6:0 A G 636 C4:0 17 rs470578491  53074609 A G C6:0 A G 637 C4:0 17 rs209474685  53075027 A C C6:0 A C 638 C4:0 17 rs442299364  53075861 T C C6:0 T C 639 C4:0 17 rs209723941  53076386 T C C6:0 T C 640 C4:0 17 rs468384620  53076606 G C C6:0 G C 641 C4:0 17 rs455946322  53076818 T G C6:0 T G 642 C4:0 17 rs211126328  53076897 T C C6:0 T C 643 C4:0 17 rs208545225  53076931 A G C6:0 A G 644 C4:0 17 rs210323226  53076936 T C C6:0 T C 645 C4:0 17 rs471850752  53077298 A C C6:0 A C 646 C4:0 17 rs463715300  53077601 T C C6:0 T C 647 C4:0 17 rs479051665  53077974 G GT C6:0 G GT 648 C4:0 17 rs477658921  53078216 G GAAAGTGA C6:0 G GAAAGTGA 649 C4:0 17 rs211135086  53078316 C T C6:0 C T 650 C4:0 17 rs207911941  53078394 T C C6:0 T C 651 C4:0 17 rs210115102  53078460 A C C6:0 A C 652 C4:0 17 rs382245802  53078595 C T C6:0 C T 653 C4:0 17 rs451762433  53078815 GT G 654 C4:0 17 rs209787441  53079293 C T C6:0 C T 655 C4:0 17 rs211616670  53079307 A G C6:0 A G 656 C4:0 17 rs208766232  53079405 C G C6:0 C G 657 C4:0 17 rs210631983  53079464 A C C6:0 A C 658 C4:0 17 rs211666757  53079468 C T C6:0 C T 659 C4:0 17 rs208735464  53079507 C T C6:0 C T 660 C4:0 17 rs448754537  53079557 G GT C6:0 G GT 661 C4:0 17 rs209241644  53079602 C G C6:0 C G 662 C4:0 17 rs452024516  53079609 TC T C6:0 TC T 663 C4:0 17 rs210089874  53079641 T A C6:0 T A 664 C4:0 17 rs210545931  53079660 A G C6:0 A G 665 C4:0 17 rs378278234  53079698 A T C6:0 A T 666 C4:0 17 rs474259058  53079752 A G C6:0 A G 667 C4:0 17 rs211135705  53079788 G A C6:0 G A 668 C6:0 17 rs441081928  53080179 A G 669 C4:0 17 rs207630811  53080284 A G C6:0 A G 670 C4:0 17 rs41638800  53080800 A C 671 C4:0 17 rs41638803  53080902 G A 672 C4:0 17 rs211197242  53081441 A G C6:0 A G 673 C4:0 17 rs381484462  53081452 T C C6:0 T C 674 C4:0 17 rs381040511  53081745 C T C6:0 C T 675 C4:0 17 rs471482330  53081900 T A 676 C4:0 17 rs379587739  53082256 A T C6:0 A T 677 C4:0 17 rs384944618  53089449 C T C6:0 C T 678 C6:0 17 rs477456528  53090245 T C 679 C4:0 17 rs453170809  53091178 T G 680 C4:0 17 rs445816688  53092921 A G 681 C4:0 17 rs381627279  53092938 C T C6:0 C T 682 C6:0 17 rs136527636  53101097 G A C8:0 G A 683 C8:0 17 rs378585850  53102051 AGAGCCT A 684 C4:0 19 rs110710863  37420803 C T 685 C4:0 19 rs110201122  37420824 T C 686 C4:0 19 rs110171922  37421093 T G 687 C4:0 19 rs110370931  37421119 A G 688 C6:0 19 rs110601471  37421292 C G 689 C4:0 19 rs133598433  37421427 T C C6:0 T C 690 C4:0 19 rs109273604  37421447 G A C6:0 G A 691 C4:0 19 rs110609264  37421511 A G C6:0 A G 692 C4:0 19 rs476079746  37421626 GAAAAAA G C6:0 GAAAAAA G 693 C4:0 19 rs110416810  37421766 A C C6:0 A C 694 C4:0 19 rs137408608  37421789 T C C6:0 T C 695 C4:0 19 rs379413235  37421873 T C C6:0 T C 696 C4:0 19 rs382079281  37421874 G A C6:0 G A 697 C4:0 19 rs109168645  37421939 C A C6:0 C A 698 C4:0 19 rs137183595  37422196 C T C6:0 C T 699 C4:0 19 rs135812358  37422409 C G C6:0 C G 700 C4:0 19 rs133509820  37422432 G C C6:0 G C 701 C4:0 19 rs134576159  37422449 C T C6:0 C T 702 C4:0 19 rs136067775  37422461 A G C6:0 A G 703 C4:0 19 rs133648926  37422538 A G C6:0 A G 704 C4:0 19 rs134775921  37422561 A G C6:0 A G 705 C4:0 19 rs137767490  37422691 C A C6:0 C A 706 C4:0 19 rs109729348  37422810 T A C6:0 T A 707 C4:0 19 rs135001727  37422935 T C C6:0 T C 708 C4:0 19 rs133802021  37422972 T G C6:0 T G 709 C4:0 19 rs135728427  37423317 A G C6:0 A G 710 C4:0 19 rs133979612  37423324 T C C6:0 T C 711 C4:0 19 rs135123627  37423391 CT C C6:0 CT C 712 C4:0 19 rs134162730  37423657 G C C6:0 G C 713 C4:0 19 rs137382226  37423683 C T C6:0 C T 714 C4:0 19 rs109960587  37423701 T C C6:0 T C 715 C4:0 19 rs134677753  37423782 G A C6:0 G A 716 C4:0 19 rs133315299  37423848 G A C6:0 G A 717 C4:0 19 rs137181081  37424353 C G C6:0 C G 718 C4:0 19 rs135802186  37424369 A C C6:0 A C 719 C4:0 19 rs136803646  37424464 C T C6:0 C T 720 C4:0 19 rs135719507  37425463 C G C6:0 C G 721 C4:0 19 rs134757858  37425768 T G C6:0 T G 722 C4:0 19 rs135912187  37425818 G A C6:0 G A 723 C4:0 19 rs133675471  37426461 G A C6:0 G A 724 C4:0 19 rs137377991  37426466 T G C6:0 T G 725 C4:0 19 rs133655171  37426504 C CT C6:0 C CT 726 C4:0 19 rs136258047  37426562 T C C6:0 T C 727 C4:0 19 rs136959782  37426570 A G C6:0 A G 728 C4:0 19 rs135043167  37426743 T C C6:0 T C 729 C4:0 19 rs134134839  37427073 G A C6:0 G A 730 C4:0 19 rs134357578  37427295 T C C6:0 T C 731 C4:0 19 rs135860451  37427334 T C C6:0 T C 732 C4:0 19 rs132850606  37427373 A C C6:0 A C 733 C4:0 19 rs134153528  37427512 C A C6:0 C A 734 C4:0 19 rs137607495  37427695 A G C6:0 A G 735 C4:0 19 rs137124042  37427696 C T C6:0 C T 736 C4:0 19 rs135479468  37427811 T C C6:0 T C 737 C4:0 19 rs208812779  37427934 C T C6:0 C T 738 C4:0 19 rs210462806  37427947 T C C6:0 T C 739 C4:0 19 rs211367926  37427957 A G C6:0 A G 740 C4:0 19 rs380334338  37427983 G A C6:0 G A 741 C4:0 19 rs378112208  37428145 T A C6:0 T A 742 C4:0 19 rs381773378  37428203 G A C6:0 G A 743 C4:0 19 rs384061903  37428214 G A C6:0 G A 744 C4:0 19 rs381452316  37428217 G A C6:0 G A 745 C4:0 19 rs454426041  37428406 T TGCTG 746 C4:0 19 rs133864523  37428532 A G C6:0 A G 747 C4:0 19 rs109760848  37428964 G C C6:0 G C 748 C4:0 19 rs136957290  37429174 T C C6:0 T C 749 C4:0 19 rs135031930  37429200 G A C6:0 G A 750 C4:0 19 rs136577796  37429299 C T C6:0 C T 751 C4:0 19 rs134461158  37429505 C T C6:0 C T 752 C4:0 19 rs470727529  37429535 GTCA G C6:0 GTCA G 753 C4:0 19 rs132894782  37429584 T C C6:0 T C 754 C4:0 19 rs379929109  37429611 G A C6:0 G A 755 C4:0 19 rs207642909  37429715 G C C6:0 G C 756 C4:0 19 rs377908592  37429731 C T C6:0 C T 757 C4:0 19 rs385022671  37429766 G A C6:0 G A 758 C4:0 19 rs384668978  37429842 C T C6:0 C T 759 C4:0 19 rs381945799  37429893 C G C6:0 C G 760 C4:0 19 rs378103579  37430038 G A C6:0 G A 761 C4:0 19 rs379612849  37430398 T C C6:0 T C 762 C4:0 19 rs209313162  37430599 G A C6:0 G A 763 C4:0 19 rs137694497  37430691 T C C6:0 T C 764 C4:0 19 rs133969987  37430745 G A C6:0 G A 765 C4:0 19 rs208203050  37431116 G C C6:0 G C 766 C4:0 19 rs209459815  37431323 C T C6:0 C T 767 C6:0 19 rs134974631  37431439 A AGTAT 768 C4:0 19 rs134982853  37431723 C G C6:0 C G 769 C4:0 19 rs132959868  37431903 G A C6:0 G A 770 C4:0 19 rs135144890  37432217 A G 771 C4:0 19 rs136585582  37432258 G A C6:0 G A 772 C4:0 19 rs134430106  37432259 G A 773 C6:0 19 rs136278512  37432404 G A C4:0 C T C6:0 C T 774 C4:0 19 rs133391765  37432454 C T C6:0 C T 775 C4:0 19 rs134565972  37432565 A C C6:0 A C 776 C4:0 19 rs136065115  37432605 A G C6:0 A G 777 C4:0 19 rs133641031  37432642 A G C6:0 A G 778 C4:0 19 rs135308492  37433580 T C C6:0 T C 779 C4:0 19 rs136163473  37433644 A G C6:0 A G 780 C4:0 19 rs134866950  37433917 A G C6:0 A G 781 C4:0 19 rs137830904  37434273 A T C6:0 A T 782 C4:0 19 rs133758652  37434308 G A C6:0 G A 783 C4:0 19 rs135079368  37434328 A C C6:0 A C 784 C4:0 19 rs135793795  37434398 C T C6:0 C T 785 C4:0 19 rs134005788  37434407 C A C6:0 C A 786 C4:0 19 rs133547101  37434481 A G C6:0 A G 787 C4:0 19 rs132832565  37434487 A G C6:0 A G 788 C4:0 19 rs137090886  37434518 T C C6:0 T C 789 C4:0 19 rs136064330  37435003 T TCTGA C6:0 T TCTGA 790 C4:0 19 rs136671929  37435359 G A C6:0 G A 791 C4:0 19 rs134672095  37435570 T C C6:0 T C 792 C4:0 19 rs136283595  37435651 C T C6:0 C T 793 C4:0 19 rs137840008  37435743 A AAT C6:0 A AAT 794 C4:0 19 rs133591435  37435788 C CCACAAAA TGAGTTTT GG C6:0 C CCACAAAA TGAGTTTT GG 795 C4:0 19 rs135485508  37435982 T C C6:0 T C 796 C4:0 19 rs134871207  37436054 C T C6:0 C T 797 C4:0 19 rs137633584  37436062 A G C6:0 A G 798 C4:0 19 rs133408506  37436088 A G C6:0 A G 799 C4:0 19 rs137244033  37436090 T A C6:0 T A 800 C4:0 19 rs135981635  37436245 G A C6:0 G A 801 C4:0 19 rs133519775  37436425 C G C6:0 C G 802 C4:0 19 rs134784649  37436570 C T C6:0 C T 803 C4:0 19 rs135868292  37436588 A G C6:0 A G 804 C4:0 19 rs135105101  37436847 T TTGGTTCC CAAGACAG C6:0 T TTGGTTCC CAAGACAG 805 C4:0 19 rs133602694  37436886 C T C6:0 C T 806 C4:0 19 rs134512402  37436977 C T C6:0 C T 807 C4:0 19 rs137828242  37436988 C G C6:0 C G 808 C4:0 19 rs133799248  37437026 A G C6:0 A G 809 C4:0 19 rs133883757  37437039 A ACC C6:0 A ACC 810 C4:0 19 rs132715652  37437163 T C C6:0 T C 811 C4:0 19 rs110189669  37437563 G A C6:0 G A 812 C4:0 19 rs109530290  37437573 G T C6:0 G T 813 C4:0 19 rs41576369  37437695 G A C6:0 G A 814 C4:0 19 rs41576370  37437821 A G 815 C4:0 19 rs135468541  37438010 C T C6:0 C T 816 C4:0 19 rs136678786  37438105 T G 817 C4:0 19 rs134336883  37438112 T C 818 C4:0 19 rs137607056  37438113 G A C6:0 G A 819 C4:0 19 rs133108726  37438114 T G C6:0 T G 820 C4:0 19 rs134873693  37438226 G A C6:0 G A 821 C4:0 19 rs135640211  37438269 A G C6:0 A G 822 C4:0 19 rs133351905  37438337 A C C6:0 A C 823 C4:0 19 rs137241977  37438365 T C C6:0 T C 824 C4:0 19 rs135974828  37438383 C G C6:0 C G 825 C4:0 19 rs137028398  37438429 A G 826 C4:0 19 rs110201546  37438468 G C C6:0 G C 827 C4:0 19 rs136172294  37438784 C T C6:0 C T 828 C4:0 19 rs133860679  37438863 A C C6:0 A C 829 C4:0 19 rs135538891  37438870 A G C6:0 A G 830 C4:0 19 rs133066628  37438939 A G C6:0 A G 831 C4:0 19 rs137103770  37438958 AG A C6:0 AG A 832 C4:0 19 rs133819098  37439297 A G 833 C4:0 19 rs137438705  37439300 C G 834 C4:0 19 rs132754289  37439381 C T 835 C4:0 19 rs137181696  37439454 G C 836 C4:0 19 rs135564283  37439496 A G 837 C4:0 19 rs134154369  37439746 T C 838 C4:0 19 rs135333508  37439816 C T 839 C4:0 19 rs136839550  37439830 T C 840 C4:0 19 rs134774547  37439869 T A 841 C4:0 19 rs41576372  37439918 C G 842 C4:0 19 rs135774487  37440020 C CA 843 C4:0 19 rs41576371  37440101 A T 844 C4:0 19 rs137347913  37440250 C G 845 C4:0 19 rs136518355  37440578 G A 846 C4:0 19 rs133518147  37440629 C A 847 C4:0 19 rs135080269  37440705 G C 848 C4:0 19 rs137036091  37440870 T C 849 C4:0 19 rs137757787  37441036 A G 850 C4:0 19 rs133731495  37441042 A G 851 C4:0 19 rs134981038  37441076 T A 852 C4:0 19 rs132957417  37441125 T A 853 C4:0 19 rs134239990  37441243 T A 854 C4:0 19 rs135142449  37441273 A G 855 C4:0 19 rs132748248  37441281 T C 856 C4:0 19 rs137179189  37441306 C T 857 C4:0 19 rs135794148  37441360 C G 858 C4:0 19 rs136685374  37441365 C CA 859 C4:0 19 rs136090847  37441412 C G 860 C4:0 19 rs135345504  37441479 G A 861 C4:0 19 rs136451321  37441591 C T 862 C4:0 19 rs133208066  37441708 C T 863 C4:0 19 rs137212631  37441806 A G 864 C4:0 19 rs136257382  37441808 G A 865 C4:0 19 rs136959108  37442365 A C 866 C4:0 19 rs134396590  37442684 C CA 867 C4:0 19 rs135065747  37442917 T C 868 C4:0 19 rs135788452  37442938 G A 869 C4:0 19 rs134002361  37442979 C T 870 C4:0 19 rs136223156  37443245 C CCTG 871 C4:0 19 rs135205937  37443292 C T 872 C4:0 19 rs472388394  37443331 T TGGGATTC TCTA C6:0 T TGGGATTC TCTA 873 C4:0 19 rs136613713  37443426 G A 874 C4:0 19 rs134151301  37443497 A T 875 C4:0 19 rs133021715  37443823 C T 876 C4:0 19 rs134773341  37443851 A G 877 C4:0 19 rs136303013  37444043 A G 878 C4:0 19 rs133271003  37444088 T C 879 C4:0 19 rs134904840  37444601 A G 880 C4:0 19 rs137789177  37444654 G A 881 C4:0 19 rs136810376  37444705 T G 882 C4:0 19 rs134580708  37444849 A G 883 C4:0 19 rs137534572  37445264 C T 884 C4:0 19 rs133511250  37445303 G A 885 C4:0 19 rs134781037  37445766 C G 886 C4:0 19 rs135866327  37445876 G A 887 C12:0 19 rs41921229  51307470 A T 888 C12:0 19 rs41921230  51307589 T G 889 C10:0 19 rs135377429  51308704 T A C12:0 T A C14:0 T A 890 C10:0 19 rs41922135  51310989 T C C12:0 T C C14:0 T C 891 C10:0 19 rs41922136  51311036 T G C12:0 T G C14:0 T G 892 C14:0 19 rs41636874  51312886 G A 893 C12:0 19 rs41921153  51317626 G C 894 C12:0 19 rs41921154  51317647 T C 895 C12:0 19 rs41921156  51318839 T C 896 C12:0 19 rs41921157  51319275 C T 897 C12:0 19 rs41921178  51326867 T C 898 C12:0 19 rs41921180  51327163 A G 899 C10:0 19 rs136995961  51327392 C T C12:0 C T C14:0 C T 900 C10:0 19 rs382822995  51328364 TC T C12:0 TC T C14:0 TC T 901 C12:0 19 rs41921183  51329756 T C 902 C10:0 19 rs134213494  51329757 G A C12:0 G A C14:0 G A 903 C10:0 19 rs457952543  51334328 C CT C12:0 C CT C14:0 C CT C18:1cis-11 CT C 904 C10:0 19 rs135163996  51342769 G GT C12:0 G GT C14:0 G GT 905 C10:0 19 rs210011361  51343102 T A C12:0 T A C14:0 T A 906 C10:0 19 rs136902713  51347031 A G C12:0 A G C14:0 A G 907 C10:0 19 rs135090927  51349516 C G C12:0 C G C14:0 C G 908 C10:0 19 rs210269014  51367626 A G C12:0 A G C14:0 A G 909 C10:0 19 rs137787102  51372470 C T C12:0 C T C14:0 C T 910 C10:0 19 rs135860613  51373688 T C C12:0 T C C14:0 T C 911 C10:0 19 rs109016955  51381233 G C C12:0 G C C14:0 G C C18:1cis-10 C G 912 C10:0 19 rs136067046  51383847 C G C12:0 C G C14:0 C G 913 C10:0 19 rs110674576  51386344 A G C12:0 A G C14:0 A G 914 C10:0 19 rs137117849  51388187 G A C12:0 G A C14:0 G A 915 C10:0 19 rs110687534  51388582 G A C12:0 G A C14:0 G A 916 C10:0 19 rs446880702  51410942 T C C12:0 T C C14:0 T C C18:1cis-9 C T

TABLE 2 Polymorphisms including flanking sequences. A = Adenine, G = Guanine; C = Cytosine, T = Thymine. ″n″ indicates the polymorphic site, ″n1″ represents one of the alternative forms of the polymorphism and ″n2″ represents the other alternative form of the polymorphism. P# SEQ ID NO Flanking Sequence n1 n2 1 TCTATATCCCCTTAGTCCCACTTAAGTAAAGTTCAACACTAGCCGGTAGCATACTCAGTnAGTGGTGGGTAGGATGATAATGCAAGAGAGCTGACCAAAGAAATACAACAACAACGGCAA A C 2 TTTAAGTTTCTGATTTACAGATGTCTTCCCAGAAAATGATAATGGTGTAAAGAAAGATAnACGTCGACATTCTATTCTTGGTTCTTATCAAATAGAGGAAGGTCTGGCTAAGGGTCAGGG A C 3 CACCTCAGAAGTGACACAGTCCAGACAGGCTACCTGTCTCCTTATTTAAAAAAGGGGGGnAAAAGGGCTTTCTTTGTTTCAGTTTTAGAGGCAGTAAATACCTTTGCCTTGGAGCTATCC A G 4 ACTCAAAGCACCTTGATTTGTAATAGCCAAAAACTGGAAACAACCCAAATTGTCCATCCnCAAGTGAATGCATGTACAAACTGTAGTATACTTGAACAACAGAACACTATACAGAAGTAC A T 5 AATATAAATCAGGTATTAAAAGTGATGTACGAGAATAAAATACATGAAGGGATAGTAAGnTGTTTGTTATTTTAGATAAATAATTTAAGAAAGACAGCTATCCACCCATGTCCACATTAT A G 6 CCTTTTGGGGGCTTGGTGTGTGGTTTGGCCCTGAAGGCCTACTGAGTTATGTAGGGCTGnCTGTGTCTACACCTGTGATTCTCAAACTGCCCTTTAGGAAAGAATCACCCTGTATGCTTG T C 7 CATACAATGAAAATTTATAGGCTTTAGATTTGGATAGAACTGAATTAAAGTTTTGCTCAnAATCGCTTGCTTAACTGTGTGGCTCTGGGTAATAAATAAGGTGGAAAGTACATTTTTTGA C A 8 GCAATACTTTCTCGTTGCTATGTTGTATTCCTCCTATTCATAATACCAATGATGGATATnAGGATTATTTCTAGTTTTTAGCTTTCAGGACAAAGATGGCTGAGAAAATTCCTGCATACA A G 9 TTATCTTGGTATATAAGCTACCCCTTCCTGGAATGTCTTCCTTCCAAATTCACTTCTTTnTATGTCCTCCCCTTCTGAATTCACATCTTTAAAATGCCCTCCATTTCTTAGATCAGGCTT T A 10 TTTTGGCCAATCCAATAAAATAATCCCAAGAAAGAATAGATAGATAAGGATATGAAAGAnTGAGCAAAGTAAGAAGTGTACCCACAGAGTTTAGTTAATTTTACTATTTTCTTTGATGAT G A 11 ACCTTGAGAGCAGTACACTAAGTGAGATAAGCTACACAGAGAAAGATGAAAACTCTGTGnTATCACTAATATGTGGACTCTAAAAATCCTGAACTCACAGAAAGAGACAAAATGATGGTT G A 12 TTGTTAAACCATTAGTAACGCTGCCATGGTGGGAGTATTGACACTGTGGAAATTGGCAAnTACTACAAATTAGAGTTTGTTTTTTTGTTTTGTTTTGTTTTGTTTTCCCCAGAGAGCTGC G A 13 GCATTTGGCAGGCAGGTTCTTTACCACTGTGTCACCTGGAAGCCTAACGTTTCAGTACCnTAACAGAAATCGGAAAGTGTAAAAATCTTTAAAGACACCATCTTTCATGATTGAAAGAAA A G 14 TAATAATATGAGATAAAGTCCGAGTCTGAGGGGGTATTAAATGTACTCTCAAACTGGTTnTCTAGCAATTACAGCGTTGTCAGGATAATAAACAGGGGTGCTATTCTGGGTAATAAAGCA C T 15 CCTAAATCCTGACCCTCTGCTGTCCAGAGCCCCGGGCAGCTCCTGGTGGCAGTAACACTnGTCCTCTCAGCCTGGGTCACCCTTGATGGAGGGTGGACGAAGCAGAGTCCTGAGCTGCGG A G 16 TCAACACAGATGGGGAGATGTAAGCCTGGAGCTGGAGGAGCACCTGGCTAGGGTCTAAAnGCAAGTCAGAGGTGGGCGGTGGAGCCTGGGGTCTCAGCCTCAGACCCCCCAGGCCCCTGT G A 17 CATCATAACTGTAATGCTCGATCATGGTTGCTCGCTCTGCTAGAGACCGTCTCTCTTCCnTGTGATCCTGTGGGAGCATTAGTGAGTGACTAAGGACTGAGATTTCAGGGTCCTATCCAT C T 18 TTATGAGGAAACTGAGGCTCTGAGAGGCAAAAAGAAGTTGCCCTGGTTCAAAAGAAAGTnAAAGCTTCTCTCCCAGTTTTGTCCTTATTTCCCACAGATGTCTTCCATGCTCATAGTCAT C A 19 CTGACTACTACATTAACATCTCCTTCCCCATGATATTGATTTTAGGTATAATGAATCTCnCGGAATGATGAGAAATTCACAAAGATTTTATCAAGTCTACACTATTCAAAATATGACAAG T C 20 TATGAGTGGGACAGACACGCTAGACAGAGTTCTCCATACACAGGGAACTCAGTGAACTCnGGGTTATCACTCTACTGTTTTGAAGATAGATTTTATACTAAGGAGTACTGTGTGGGGCTC G A 21 TTACCACTAGCGCCACCTAGGAAGCACCAGCTGTAAAGTCACCATGGATTTTAAACTCAnAGAGGGTAGGCACCCCTAAACTCCTCAACTTTCAAGAGGCAACTGTATTTGCATACAATC A G 22 ATCCTTGGCAAAGCACTTGCTTCTATTTCAGTGAGCATCTATCATTTTTCTATTAAGAAnGGAAAGTAAGCTCTCAGATAATGTCGTCTACCTTTTCAGTAATAGTCTCATTGTTGTTTA A G 23 GGAATGCTAAAGGCAAATCTTCATAGTGTCCAGCTATCCCTATAGGGAAATCCATTCAAnTTAACTTTAAAAACTTACTCTCCTGGGGACAGAAATAAGAACTAGACACTATGTGATCAA A C 24 GCTATGCTTCACCTTTGCATTTTCACATGATTTTCAGAATAAGCTTATGGACAAAAATGnATCTACTATGACTCTGAGATGGCATTGAATTTATCAATCAATTTGGGAAATGTTTAAGAA C T 25 AGCACCTTCCACTCCACAGCACACAGATGCAACACCTGGACATCAGCAGCACAACTCCCnATCAAGAAACTTGCTGTTAAAAAAAAAAAATCCATGAAGAGTAATGGGATGGAATGGCTG C A 26 AAAGATGCTCAACATTGCTGATTATCAGAGAAATGCAAATCAAAACTACAGTGAGGCACnATCTCACACCCGTCAGAATGGCTACCACTGAAAAGTCTACAAATAACAAATGCTGGAGAG G C 27 TCCCCACCTAGTTCATGCTCTCCTGAAATGCTCATGGTCAGAGCAGCAGAAACAGGGATnGGTGGCTGAACTCCAAATACCTAAAGGAGCCCCCAGCCAGTGGAGAGTTATCTGTATGCA A G 28 TATGGGGAATGGGTCCATGCTGCGTCATTGAACAGATTATTTATCTTTTTGAAAAGGTCnTGTATGTTTAGCGTGAAGATTCATCAGGAGCAGAAAATATAAAATGAAAAGTAAGCTTCC A G 29 TCCCGAAGAGACGCCGCTGTGCTTGTTAGCTTTAAGAAGCACACAGCTTTATTGACAAAnGCATCACCTCCATAACTAAGAAAAGGGGTGATCGACAATTTCATATTTCCACTTTCAGGG A G 30 AAAACACAGTCTTGCATTTTAAAACTCGGCAATAAATACGAGAAATCCATTCATTGAGAnCCATCTTCATTACTGAAATGGAAATAGATTCACTGAGACATTATTGACTATCTCACGAGA G A 31 AGGGGTAGGTGAGGGAGAAGAAGGTGCCAGGCTGATCACCTAGGGCTGGTGACGAGTTTnGGGTTTTATTATCTGTGCTAGAGGCTAGTAATGAGGTTTATGTGAAGTGATGTGATGGGG G T 32 TTTATTGACACAGGGCCACACACACCTGTTGAGGAATTACCATGGCAGCTTTTCTGTTAnAACAGCAGAGTTGAATAGTCATGACAAACCGCAAAGCTTGACATATTCACCATCTGGTCC C A 33 AGCAGCTAAGCACAGCACAGGGTTGCCTGTAGTTTTCCAGTAGAGCATGGGTTTCTGAAnCCATCGTTAGAAGAGGCCCCAAGTTGCTATCTGAGCACTGGGTTCAGCCATCACTTCTGC G A 34 GGCATTTTGTCTGTCTGTAGTTGTTAACTATTACAGGCAATGCTGTAAGTGTTATCTGTnTAGTCTTAGAAGTGGCAAAAGCCTCCTTAGGTCATCAGTATTGTCCTCCTTGCCCTCTTG A G 35 ACCTGTTAGCTTCCTGCCCTTTTTAAATGAGTTATCTAATCTCCTTATACCGTACCTTAnTTATTTGTAAGTAAATAATGGTGTTGGCTTCCCAGCCCGGTGGTAAGGAATCAGCCCGCC A G 36 TTTAAAAAAATAGCTTTTGAAAAGATTTCAGGTAATTTAATTGGTATTTCTATTTACTTnCTCAGTTTGGTCTTAAATACTTTATATTGGTGTTTAAAGTTCTCCATTATTAGGAAGAAA A C 37 TGTGTTTTCTGGAATATTAGGGAATATGGTAGTGAAGAGTTCTAACCTTGAGGCTATTTnTCCAAGTTAAAATGGTCTTGAAGATTCCCATTAAGCTCGAAGGTTGGGAACTGGGTGGGT C A 38 TTAGGAAAGGGGCAAAAATGAGCCACTTTACAGTGGAGAAATTCAAATAATACTACCTTnTCCATGTTCTCAATATCACCATCAACAGTGATGTTGGTAGTGTGTATCCTTGATATAATG T A 39 GAGGGAGCTGTCGATTGGACATTTTCCACCAAGAAAAGCAGTTGCTCTTCAGTTTCAAAnATAGTTACACCTAGTTTTGATATTTATAATACCAGCAAGACAAAGCGTTCTAAACAGATA C G 40 AAGTGTGGGAAGCAGGCACAGACTCCCGTGCAGAGAGAAGGTGCCAAGAATGAGGCCATnGTGGAGGAAATGATGCACAGGTGACTGGGGAAGAAAAGGGAACAGGAAAGGTGAGAGGAA C T 41 TTTCTGTCCTCTCTTCAGAGATGACATATTTTTATTCTAGGCTCAAAGAAGTGGGGAAGnGTAAAGGGTAAAATAGGCTAACAAATTCTTGCTGCTGCTGCTGCTGCTGCTAAGTCACTT G T 42 TTTGCTAAAATATGAGCGAACAAGTCCAGTGTAGGGAGTTGAACAGAGCACTATGGTATnGAGTGTGTAGTTTCTTGCCTTACGATGCCTACTATGATTTTAAAGTTACTTAAAATTGTT T C 43 TGTGATCAGTCAGCAGACAGAGGACAGAGCTGCTGAGGTCTTGGGGGCCCAATGGGTACnTGGGTGCTTGTAACATTCCTGAGGATAGTAGGGACTCTTTTGATAACAGCCTTTCTCTGG T C 44 GTAAACAGTCTAACTGCATCCCAGATGCAGAACTCTCATATTCCGGTTATTACAGGCTGnCAGAGGAGCCCCTGATTCCTCTCCCAGCATCCTAGAAATGTACCTGATGTCCTCTGGTGA T G 45 ATAGAACCAATATTTCTCAGCTCAGGATATCATTGGTATAAAATCTCCAATTGCCTGAAnGCTGATTCTTCCTCGTGCTTCAAAAAGCTCGTCTCTGCTTCTCTCCTTTCCCCAAGGTGT T C 46 AATGAATACCCACAATCTTTCCTGAATAAGCCATCTTCTTCCCAACTGATTAGAAACAAnGCTTTTATAAGTACTCATTTTTATTTTGTATAATGATCAAATGTACCATCTATTCTCATT C T 47 CCACCCCCCAGGTGCGCACCCGGCTTCTTCGGGAACCCCCTGGTGCTGGGCAGCTCGTGnCAGCCCTGTGACTGTAGTGGGAACGGTGACCCCAACATGCTCTTCAGCGACTGCGACCCC C T 48 GAAGTGGACCCTCCAGGCTTAGGCAGGAGGATTCAGGAGGGGTTGTCTGCTCAGGGAATnGGGTGGTTGTTGGGAGGTGCAGAGGAAGGAAACCAATGTTTTTCTCCCTTTGCCCCCATA G A 49 AGGGCTACAGTCCATGGGGTCGCAAAGAGTTGGACACGACCGAGCCACTAACATTGTCAnTCACCAGTCAGGATGCACAGCACTTCTGGTCCATCTCTGTTCCCCTGCTTGCTCCCCCAG A G 50 TGCTGCGACTTGCTTAGCTTTTCCTCCTCTGTGCCCTTGATATTGCTGCCTGTGGTCACnGTGATTTTGCTGGGGTCCTGCACACAAACCAAAGAAAGGGAGACACTTGAGGGCAGGAGC A C 51 GCATGGCAGAGCAGAACAGTAGCAGTGCTTCCTCAGCCACTCGGCAACAAATGCCTCCTnCACCCCAAAGGAAGACTGACGAAAAGTTCTAAAATTAGAAGATGAGCTGGGGCTGAAAGG G T 52 TTTCTAAATAATTTAAAAGAAAAAGGAGACTAACTCCAGCAATGAAAAGGACAGGCAAAnGACATCAAAATAGAGGGAGAATGCTAATTAATACCAGTGTTTAGGAAGGCAACTGGGCAA G T 53 TTAGTCCCTCAAAATTTAGTTCATCATGCATTATCTCAGTGAAGCCCTTCCTTCTATATnCTGTCCTAACTCAACCCTTCAGAATAATCACCCTCTGTGAGCTTCAACAGACCTGAGACA A C 54 GGCAACACGGTATGGACGTTCGGGGTGAGACACAGACCTGTATGCTATACCAAGGGGCCnAGGCTGCTGCTTCCTGCTCAGAACATAACCCAAGGCTGTTCAGTCCAATGGGCCCTCTGC G A 55 TTGTGTGACCACAGGCACATCCTTCTCTTACAGTACAATCGCCCCTTTTACACAAGGAAnAGAATGGAAAGGAAATTTTCAATCAGCAAACTCTAAAGGAGACACAATTTGGGACTCTAT G A 56 AGGTGGCTCCAGGCTGTTCACAGTCTCCTGGGAGTGGTTACCTGCACCAGTAGGGTCTGnGAAGTGAGAACAGAGGACAGTCCTTCTTCCTCCAAATCTAAACCCTGAAAGCCTTTTGCA C T 57 TGGGGCCACTCCAGGTACCAGTATGGAAAGGTGAGGGGGGGTAGGTGGTGTGCCAGCACnATGCTGCGAGGGTGGTCCTCCTTCTGGAACACTGTTCAACATCCGGAGGATGCAATGGAT G A 58 GACAGCAACCTCCTGGGAGACTCTGAGCCAGAAGCCCCCACCCATACCAGCTGCAGAGTnCTAGAAAAAAGTGGATCTCCTGACAAAAAGTGACCAGATCCGCTGAGTACAGAGGAAGAG C T 59 CCTCAGGGAAGCCTTCCCCTTTAAAGCCACACAGTCGGTCACTCAGGCTTCCTGTCCGCnGTGGCCTGTGTTTGCATTAGTAGCGCTCTTATCCCAGGATCTCATAAGTAGCTGTTTAAA A C 60 CCGGGAGTCACTCAAAAGTAATGCCCAGAACTCCAGCCCAGGCTGTGCCTCTGAGTAAGnGAGGGCCCTCCTGGGCCTCAGTGGCCTTACCTGAGAAATGGGACTTGATTGTGTGTTTGT C T 61 TGGGGGCGAGGGACGCTGACTCCCAGTCCCGGATTACTAGGTCTAAAGTTGAGTTGACTnCACTTCTGATTCTGATCTCAAGGCGTAATCTGATTCTACAGAGTTGATATTCTACATGGA A G 62 CATTTATTCCCAGAATCCAGAGGGCTGAACCAACAAGCACCCCTCTTCACCCCATTTGAnGAAGGGACCAATCTAGCCTCCAGCTGGAGACATCACAGGTCCAGGGTTTGTGAGGCTGCA G A 63 GAGTCCCCCTTACCCCATGGACTTGGATCTCACCAAGGGCAGGACTGAGATGTCAGGAGnAAAAGAAAACTCATCTTCTTAATACAGTTATTGGTATAATCTGAAAATATGACTAATAAT A G 64 GCAGGCTGTCACCACCTGTGCCTACTGTGCCAGTGGGCTCGCAGCAGGGGCACAATAAAnGAATTGCCCCTCCTCACTGTGTGTCCCTGTTCCTCCCATGAAACTGTCAGGGCACCGCTG C T 65 ATCTCAGGCACTGTTTGTTCACACCATTCCTTCTGCCTGGAGTGACCTTCCTGTACACAnGCCCTTCAAATCCTGCTTCCCTTCAAACCCCGTTTGCCACAGGCTTGGTGAATGGCTCTC C T 66 GCAAGGTGAGGAGGGATCACTCAGAACCTTTCCCATTGCCACGCAGAGGGCATAGGCCCnAGAGGTAAGTAACCAGGCTTCAGATCAGAGCCAGACCAGGCAGAAACTCCAGGCCCTTGT A G 67 CCCAGCCTTAGTCAGTTCCCAAGCCCCCTCAGCAGCAAGCCTGCGGGCTGGAGATCTTGnGGTTTTCTCCCTGGTCTGTTGCTCTGACTGGGCTTCCACTGTTCAGCTGGAGGGTTCCAA A G 68 GCAAGTCTGTGCTACAAGGCTGCCTATCTGGGCTTGGGACAACTACCTCCTCCTCCTGCnAGGTTCTAGCTGAGCCTGGCCTCTCCCCATCTTTATACAGGGACCAGTTCTGTTCCAAAG C T 69 TGTCTGTACCATCAGCCCGGCAGTTGGGCAGCAGAGAACTCAGCTGCAGCGGCCAGCACnGTGGCTCTCTGCCCTTTCTCCCCCGAGACAGCCTTAAGTCCTTCCAAGAGTGGGGAGCGG G A 70 CATTGAAACTTTCATTAAAAAATAAAGGAGTGTGTACAATCCATTACTTCTGGGGCCCCnCTTCCTAGACCCCACGTGACTCCTGGCTCTGGCTTCAGACACCCTGCAGGCTGCAGCCTT T G 71 TTCCAGGGAACTTTTTGCCGAAATGTCGGGGTGCCCGGCTGCAGGCACAACATAAGATCnATTTCATTCTCACCCCAGGCACTCAGGGAGGCAGAAAGTCCACAGGCTACTTGGACACAT A G 72 CCCTCTGCTCCGTGGGCCTGGAAGCTCTCCTCCCTGGAATCTGGGGCCAGAGGGGAGAAnGCCCCTGGCCTGACATCCAAGGCCGCACAGTCAGACCCTATCTATCTTCCAAATCTCTGC A C 73 TTCAGGGAGTCAAACAGACTTGAGGTTGAATCCTGACTGCCATTTGCTGTGGCATTCTTnGTGCCCACAGATCCCAGTTGACTGCTTCCCACCTGAATTAGCCCATCAGTTGACCCTTTG C T 74 GAGCCTTCTCATAGGACGCAGAAGAAGCTGACACTGGATCTGTCCCGTCACCTGAACTCnTCGGTAATTTATTGATGCTGGATGCTGGCACCTAGCAGCTTGCCGGGTCAGCCTCAGGGA G A 75 GAGGAATCTGAAACCTGAGGCCATGAGACAGCACATCTGTCTCACCTGGCTGTGTTTCCnTGGCATTTGCCTGCCCTGACATGCTGGGACCCTAGGATGTGTGAGGATCCAGCTAAAGTA T C 76 AATAATCCATTTTTTTATAGAAATTCATTGTAAAACCAATTTTTTGGCTACTGGGGTGGnGAATTTGTAACTGGATCCCGCCTTCTAGGCGGGGTCACATCTGCCCGAGGTGGGATCTCA A G 77 GACAAAGGCAGAGATTTGTATCTGGAATGAGTCAGCAACTGAGTAGGGTCCAGAAGTGGnAAGAGGGAAAGGAACTTATGAAGGTGACATTGACCGGTTAGGGTGAGGCCAGTCAAGGGT C T 78 TATTTGGAGAGGGACTCTGGGCTGGCAGCCACATTTGGGACCCCCAGAGGGTCTGAGGAnTCTGAGGCCCAGGGAGGGGCTGGGACCCGCCAAGCTCTCCCCGTGAGTCAGGTGGCTGCT A G 79 GGTCACCATGAAGACAGGCAAGAGCCTGCTGCACCTCCACGGCACCCTGGAGATGTTTGnTGCACGGTGGCGGGGCAAGCCGCCTGTATCCCTCTTTGTCCTGGAAACTGTGAGTGGACT C T 80 TGCGGCCCTGGCAATCATAGAGGTGAGTTTCCCATGGTGGGGAGGGTAAGCCTTGATGGnCCTAAAGCTTGTCTCTGGAGAGGGGACTGCTCTGCCTTTGACAAGGTCTGTCGCTGCCCA A G 81 GACTGGATACCTGCCTGGGTGACCCTTTTCTGAACCTCAGTGATCTTGTCTGCAGCATGnGCATAGTCAGGAGACCTCTCAGGGATCAACAGAAGGGCCTGAGTCCCTTGAATGACATGG A G 82 CTGAATGAGACCTTTGCTTCTCCGCAGCCATCTCGGGCACCTTGCAGCAAAGTGATGCTnTTCGCTCAGCCCTGAGAGAGGTGCCCATGGGTAAAGCTGGTGGTGATGGTGGCGGGCCTC T C 83 TCCATTCCTGGAGGCACACAGGTGACCCAGAAGGCGAGAGGGACCCAGGGGGCTGGGACnCGTCCCTGGGGGTCTGAAAAGGGCCCTAAGGAATGCGGAGGGACAGATTGGTGAGAGGAT G T 84 GGGGGTCTCACAGGGAGCCCCCAGCGAGCAATGACCGCTGTATGATGGCAGTGACATTCnATTCACCTTCCCTTTCCTCCAGGACACAGAACTCTTGGCCATGTTTTCCGTGGAGAATGA T C 85 TTGGTTCCTCCTTCGTGGAATTCCTAAAGGATCTTGCCAGGTAGTGATGATGCTCATGCnGGCATAGCACCCACCGGGTACCAGGGGTGATTCTATGGGATTTACTTGAATTACCCTATT G A 86 GACTTCCTCTCCAGCCACAGGGCTGGGGTTCGGGGTGGGGGCTCAAAGATCCCTTCAGAnCTGAGCGAATCTCTGCCTTTTCATTCTTCCTCTGCAGGTTGGCCTCTTGGAGGTGCTGGT C T 87 GGTAAGGGGAGATTAGAGCTCTGTTCTGCCTTCCTCTGCAAACCCAGGAATTGGGAGGAnGAAGAGAAGGGAAGGGAAGGGCAGGACAATAGCAGCCTCTACCTTCAAAGGATGGGGCTG A G 88 CTTGAATGGGCAATGTGGGTCAGACGCCGGCTCTGGGCCATCCTTGGGGGCACCAGTCGnGGTCCCTTCTCTTGAGCGCCTGCAGGACCTCAGCACTACTCTGAGCCTCAGTTTCCTCAT T C 89 CTCCACTGTTCAGAGTTACTGCTGCCGAGAAATGCGACTGGCCTGACCCTAAGGCAGGCnGCTGTCTGCTGAGCTGTAGCCAGAAGCCACCCCATTCACTAACCAGCTCTGTGTTCTGCC G T 90 CATTCCTCAATTCTCCCACCCCAACTCCACAGCGCACGGGGAGGGTCAGCACTCAGAAGnAGCAAGTTCAAAGTCATTAGACTGACTGCACACTGCTGGAGGGCTGCCCTCTGGCCTAAC T G 91 CTGGCCATGTACGGTCTGCTCAGAGCAACTGCTCCCCAAGCCCCATCCCAAAGCTCCTTnTCTGCCAGACAGTGAGGAAAACGGCCAATCTCTTCATGTTGAAAACAATCAGACAGCATT C T 92 GAGTCCTTGCCAGGAGAGAAGAGGAGTCTTTCTTCTTCCTATTGTCATGGGATGTGAGAnTTCCCCATTCTGGCCTCCCAACTCTACTGAAGTTTCTGTTTAATTTGTGCACCTCTGATC A G 93 GACTTTGAGGAATATTGCTTTCGTTTACCATCCCCATTGGGCAGTCAGGGACACTGAGGnGGGAAAGAGCAAGCAGGTGCCAGGGTTAGGCTTGGACTCGGTTGGGCTTGACCTCTTTGT T C 94 GGGGGTCAGGGGCCTCTGACTTGCCTTGCCTCTGATTCCTCTCCACTGGGCATGGGCCCnGGGAGACCCCCAGTGAAGAGGAGCGAACAGTAACAGAGACATCCATCCTCGTGGTCACAA C A 95 TTGGAGTAAGGAGCAAATTCCCAGGGGGCGAAGGTTGCCTTGGGGAATCAGGTGAAAGCnGTGGTTTCTTCCCAGAACTTAGTGGATGTGCCCTTGGAGACATGAGCACACCAGAGAGCC T C 96 GGATGCCGAGGGGAGGGGCTGGGTGAGGATTGTTACACTGAGTGTCTGCAAACAGCAACnATAGTCCTAGCTGTCTTATTCCATTTGTTCTACTTATGAGGAATAATTCCTGCCTCCTTC A G 97 TCTGGGTTTCTCACCAAGACTGGGTCTCAGGCAGGAGGCAGGAAGGAGATGGGACCCCCnTCAAGCAGGAGGGGCAGGCTGTTGTCCCCCTGGGGAGCCAAGGAGGGCCTGACTCATCCA A G 98 TTCCCTCAGGGAAGTCACCCATGGGCAGGGTCCCTGGTCTATGTGCTATAATAACAGCAnATGCAACATGTCAGGAGACACGTTCATCAGCGACGATCACATCGTTATGACACAGGGGAC A G 99 GCCTCCCACCCATCACCACAATATAAGGGCCATCAGCACCCAGAATTCCAGGAGACTGCnCAGTGGAGCAAGGATTTTGTAAGTATTCTCCTCCAAACCTGTGAATGGTGGGCTTCCCCC T G 100 AGGTGGTTTGCAGGGTGCTTCCAGTGGATAATGATCAGTCCTCTTTCTCTCGTGTCTCTnCTCTCCCCGATCTCCATCCCAACATCATTCCTGTCTTCCTCTCTCCATCTCCCGCTGTGT C T 101 ATGAAGGCTGCCTCACAAGGTCAACTCACGTCAGGGAACCCTTGAGCCCCTGGGGTTATnTCCGGGGCCTTCAACCAGCTCTCCTCAGCTCTGCCGAGCGGACCTTAGGTCAGGCTGTGC G A 102 TGCTTCTTAAGCTGTGTACCACACTAAATGGAGACTGTTTTGCAGCTATCTTTCAGCAAnTGAAGACTGATTTCATGCTCCCCCAGGAATCCAATACTTCTGAGGAGGGCCAGGAGAAGG T C 103 CAGACTTCAGTACACCAAGCTTCCCTGTCCTTGTTCAGAGAGATCCCATATAATGTCCAnATAGAAGAGAGACTAAAGTGGGCAATGTGAAGGGACTTCTCCATCTCCATTCACTGTGAA T C 104 GTTCTGGCTGAGAGAGAACTAGTCTGGAGTTGAAGGCTGGGGCAAGTTGGCCTTAGCAGnTAACAAGGCTGAGTCATGAGCAGAGGTCAGTTCATCCTGCCCAACAGGTGTCTGATCACA G A 105 AAAGCCTGGATGCAGATTATCTTAAGAACCACATCACTAAGTCACAGCTTGGGGAAATGnTGAGGGGGCATCCTATGCATCCTTACAGGGGAGGGCATGCTGCTCTATGCCAGCTGCACC A G 106 CAGGAGTGACAACTGAGCCCAGTCAAAGGACACTCTCAGATACTCCTCCCTACAATCAGnACACACTATGCTCATCATCCTCCATCCCCAGCAATAAAGAGCCATTTCTGCATCCTGTGT G A 107 CAGCCACCTCTCCCCAGCCCCCAGCAGGTCCCGCTGTCCTGGCCTTGATCTCTCCCACCnAGGACTGATGAGTTTTCTCTCGGGGCCCTTCTCAAAGTGCAAGTCCTCAGTTTCCCCTTT C A 108 ACCCTGCTACCTTAGTCTCCCAATCTGTAAAATAAGGAGGCCTTTGCAGCTCTAGAATCnTCACCTTTAAAATGTTCTAAGAAACTTTTCCCATAATCAAGTCTCTCTTTAAAAAGAATC T C 109 TCCAAAACTAGCAACACATTTGTAGACCATGTCTCCCTCCTCCAATCTGATGCCTACTCnAGGGTCACACAACCACACTGGGAACAACAAATATCAAAGCCACAGGAGAGCTTAGAGGTC A G 110 CTGGGGACCCAAATGCTGGGCCCTTTCCTTGTGAGATCTTGGCCAGTCACCTCCCTTCCnTAAACCTCTTTCCTCAGCAGAAAATGGGGCTTTCTGAACCTCCTCACAGAGTTGTCCTGA A G 111 CCTCTCCCTCCTCACCTCCTGGCTTCTTTCTTTCCTTCCCTCTTTCCAATTCTCTCTGCnTGTGTCTCTCTCTCTTTTGCTGGCTCTGTATGACCCTCAGCTGTGCCCACGATTCCGCGA G A 112 TTAGGCTGGCTCTGAGAACAAGCCCAGTGGCTGGGTCTGCAGTTGGCTGTGGGTTTCACnAGACAGCTGTATGGAGCTGTTAGGGGTGCTTGGGGTCAGCTTGTAGCCCAGGACTCCTAC A G 113 GTCCCATCAGTGACCTCCTGGCAACCCTCACCTGCTCCCTCTCTTTCCATCCTCACACCnACTGGCCGGGCTCATAGTCCACTTTCTGAACCTCCTCCGGCTTTCCCTGACTCAGACCTC T C 114 GGGAACTCACTGTGAATGGAAGACACAAGAAGTGATTAGATATCGTTTGAAGAGTTTCAnTGCAAATGTTCCCAGCACTGGGCCTTGGTCATCATGAAAGGATGAGAGACCCCTTCAGTG A G 115 TGCTGGATTCCAAGGGAGTGAAGAATGGTGATAGAGTGGTAAAGTAGAAACATTGCCCCnAAAAGATCTGCATTCAAGTTCAATTCAACCCAATAAGAAGTTCCATGAGCATATGGACAT A C 116 CTGGAAGGTCATAGTCCAGACAGATGGGCTAAGGTCCTGCCCAAGGCCCAAGGAATCGCnACACAGAACACTTTTGGGTGTCCAGCAAAAGAGTAAAAAGTAAAGGCTAAATTTAAAGGG A G 117 GATCAGAGCAGGCATTATTAGTTTGCCAGGTGAGGGAATTCTACCTCGTAATATAAATAnTGTCTTGAACAGGACTATAACTTTTTTCTTTTAAAATATATTTCCTAAAAGCCAACCAGT G A 118 GAAGGTGGATTTTTAACCACTGGACTGCCAGGGAAGTCCCTCCTTTCTGCCATTCTGCAnCTATTGTTGCCTCCTTCCAAACCGGGTTGATGCTGTAAAGCCCAAAGCTGACCATGTGAG C T 119 AAAAAAAGAAAGCTAAGACGCAATCAAGAATGAGATTCCTAGGCCCCATATAAATATCAnTTCTTCCAGGGAGCACTCAGGTATTGAAGTTACTGGCTTCCTCCATTGTCCACCCCAACC T C 120 GAGGCCAAGAGAGGTGGTGGCATTGATTTGACCCAGTGGTCAGACTCTAGATGAGGCCCnGACAGGGAATTCTGTCTTTATTTCAGTTGCTCAGTCCTTTCTATGATAGAGAATGCTGTA T C 121 GGCGCTTTCTCCCCGTCTGGTGTCTCGTGCAGTGCACAGCTGGGGCTCATAGGTAGCCAnAACAGCTTTGGGTTTTTTAGAGACCTTGTTTATAAATCCTTCATTTCCTTCTTTGAGCCC A G 122 GACAACGTGGGTATCAGGCTTTAGAGCTGGAATGTGGAGGATCCAGACTGCCAGGCTAAnGCATCTCTGCACAGGACATTGGGCATTTGAATTTCTTATGTAAATATCTCCTGGTCACAG C T 123 TAGTATAGCCCCCTACCCTGCCACCTAAGGGTACTTCTGTCCTTGGACTCCTGGCCCATnTGGACTTTCTTCAGGCCCAGATTGACAGAAGTTCTAACAATAAAGTTCAGAAGAATGAGA T C 124 ATTTGAAACAGGATTCCATTCCAAGATAAAAGTTGTGATTATTAACTTATATGGTACTTnTTCTTGTGTAACTTTTAAATTGCCTTTAGAATTCTAAAGATATTTTAAGCAACTTGCAGC C T 125 TCAGTATTTGGTACAGCTAGTTTGGCTGAGAAACTAAACCAGAACAAAAATTAAGTGTTnCTTCTTCCAGCTTTTGGCATGTCAGAAACTGTGGCTATGAGCCAGAAGAGTAACAGGCTT A G 126 TTAAGGGTACACAAGTAGCCTTTACAAAATCCTTCTTTGTGCGACTACTTAACCTCCCCnAAGATCAAGAAGCAGGAATCAGAAGTTATGGATTCATTGAATGTTAAAATAGGTCTTTCC A G 127 TGAGATCGTGCTGTTTTGTAGCTCAAAGGGGAAAAACAGGCAGGAGATGGAGATGCGTGnGAATGGATCAGAGATTACAAATCCACCCCTGAAGACAGACCACATTTTGCTTGGTAGGAG C T 128 ATGGGCATTGAAGCTTGAGAACCACAGCACTAGATGATATGAATGGGGTAGGGTTATAGnAATCTGTATCTTTAGCATGCTTTCCTAAGGTATATTGCAGGAAACACTGACAACGGAGGA G A 129 ATAAGGATCTTCATTACTCTCAGCCGTGGCACTCTCTTTAATGGTGGATCATGTATATAnTCTCATAATTTCCCAGCTTTAAAAGAATAGAAAAGGTAAAATCAAAGTAGTTCAATTGCT A G 130 TATTTACACATTTACACCTTAAACTTTAAAATCATGCCAGTTCATTAGTCACACTTTCTnTGATTTGACTCTTAATTTATAGAAATAACATGAATAGCCATTTTGCTGTTCCAGTTTGAA G A 131 CCCAGAAGAATTTAAACTTCATTTTTCAGGCGTTAGGGAATCATTGAAAAGTATTGACAnGGTCACATCTGTTCACAATTCTAGTAGCTATGAGGAATTGGGCTGGAGAAGTGAGAGTAA T C 132 GCATATTATAACCTTAGAATGTATTAGCATCTGGGTTCTCAGGATTCTTTATCTTGTTCnTAAACATCTAAACTTACATATACTAATAGATCAGGTAAATATGTATGGTGAGATAAACAG C T 133 TTGGGGCATATGCTTTATTTGTGGAACCAGGGATGGCTCTGATATTAAATGAGAAGCACnTGATAGACCCTCATCATTGATCCAGGAAATAAAATCCCAGTTTATAGCCTATGTTGATGT C T 134 ATAACAAAGAAGCAGTTAAGTTACATACCCCCATTATATTTTCAGAAGTGAGATGGTACnATATGAAAAAAAAAATCTCTGAATGGAGATGTCAGTTTCCATCCTGCATCAGCTAGAGTC A G 135 AAGGCCTACCACCCACGGTGATAGGTGCATTTTCTGGTGCATCTGACCCTCGCAGTTCAnCTAAGATATGAAATGATCTTTTTTTCCTTTTTTGTTTAGTATTCTAAACGCATATGACCT G A 136 ATCACTCCCGTGCAGGCATGATCTCAGACTCGAGTAACTGCCCTGCAGGACAGTGGCACnGTGCTGGGACTATAGAACGGGGGCGCTGACCACGTCCAGGGGTGGAGGGAGACGTGAGGG A G 137 TGGTTGCACCAGGTAAGGGGTCTTCCCCACCCCTACTTGAGAGCAGACCCTCACTCCATnCTTGGTAGCTATCGGGAAGGCTTCGGGTGTGGGTGTGTCCATGGGTTCCACAGAAAGGCC G A 138 CTTTCAAGCTCCTTTGTAGTGTCTTGCTCCAAGTGTCTCATGTGTCAATCCCCCACCCCnACCACCTTTATCTTTCTCTAACCGAGAACGCCACAAAGCCAAGGCCGTGTGTTTTAGTGC G A 139 AGGGAGCATCATGTGCGAATCTCCCGCCAAATCCCACTCCAGCCAGCATGCACTTCCCTnATCCTGACCCTTCCTCAGATCACGCCTCTCAGCGCAAAACCCGTGTGGGACACACCCCCT T C 140 TTGCACCCCCAGAGCTGCCAGCTAGAAAGGATTGACCTGGACTAGTGCTGGTGATTACAnAGCGTGTGCTCCCCTGTCTCTGCTCACAGAGAAGCACCGGAGACCCAGCAGGAGAGCCTC G A 141 CCACTGTTGTTAGGGAAGCTCCCAGGTACAGGCGGATTGGCCAAAGGAGTAGGACTGACnAATACATTTCTTGGCAACTCTACATTTTGCAACAAGGTTGCATTTGTTTGAGAGGCAAGT T C 142 GCAGGGCCCGGGCGGGCCTGAGGGACGTCAGCTAGGAGAGAAGTGGGGGTTCACAGGAGnGGGAGGAATTGGGGGTGTTCCGTCGGGAAATGGAAGTTCCGTGAGGAGATGGAGGTTCCC G A 143 GATATTGCTGCAGAATCCTTGAGGCCCTTCTTTCTAGTTTCCCTACCATCTGTACTTGAnTAGAGCCTGTCTTTCCACATATGTAAAATGAAAGGAGTAGATTAGATCAGTGTTTTCCCA C A 144 CTGTGCTTTGCCCTTGCGTGTACCTAGTGCCTTTTCTGTGACCATCCACACCAGCACCAnAGACTAGCTGCATTTGCTCAAAGCACTATTGACACACTTCTTCTTAAACACATTAGTGCC C T 145 GTTGTTGGGGAGGGGCTGTAGTGAGCTAGTTTCTCAAACCACAAACAGATCCCAGGGGCnGACTGCCCTCTTCCCACTCAGTCTCCATCATGTTAATAATGATTGACATTTGTAGAATTC T C 146 GGAAAAATGTGTAATGATTTGTTGGTTACAGTTAGAGAAAAGATTGGCCCCATTGCCACnCCGGATTACATCCAGAATGCACCTGGATTGCCTAAAACTCGCTCAGGTATGTTCAGAGGC C A 147 TTTGGAAAAGAATACACATCCTAGGCCCTGCTAGAGATTCTGATTCAAGAGGTCTAAGCnGAGGGAAGAGCTGAACCTCTCTTTTTAAAATAAATATTCCTGGAATGGGAACCACTGCAA G A 148 AGACATTTATGTGGCTCCTTAATGGAGGAACTGATGATGGAGGGACTGATGGAAGATCAnGTTGAAACTCTTCCGTGAGCTCTGTAAGGTTCCTAGTGTTCCTAGTTCTTGGTCGTCTTT A G 149 GTTTGTGATTGAAATTCAGAGAAAGAATTTTGTGGTTACCAGGGTAAGAAAACATCAAGnGGGCGACTGAAGTTTTTTCTTCTCATGCTAACAAGATAAAGCTGATTAACTCTGTGATGT T C 150 CTCCGTCCCTCCGTTCAGCACTGGGGGCTGCCTAGCTTCCTGCACCATCCTGTCAGCACnCTCAACCCTGCCCTGGGCCAGCTTCTCTAGGTAAAGTCTGTGGCAAAAACAGAACATAAG G A 151 CTTGCCAAAGTATTATAGGTTGTCAGCGATCAAGGAGCTTGTTTTTAAGTTCCTGAGGAnACTGCAGGCCCCCAGTCAGGATCTTTCTATTCAAACTAATTGTGAACTGAACAATGAACT C T 152 CTCACTCGGAACATCTTACAATTAATTTTTCCTCTCCTAATAATTTCTCAAAACTCCATnTCCTTCAGGTCTAGACCCCAGAAGGCTCCTTGACTATTCCAGGCTGCCCCATGGCCCCAA G A 153 GTGTGTGTGTGTGTGTGTGTATGAGAATTCAATCTGTGTTGAGAAGATCTATGGCACAGnAAGAGGGAAGTTGAAGTCCAAATACCTGTTGCTTGTAATTCAGTGAAATCAATTAGTGGA G A 154 TCCGAAGAGGGAAGACTTTTCCTTAATTCGTATGGTAATTTGGTCCTTTTCAAGACCCTnACACAATTCTGCTTCTTATATGTGCGTAAGGCATTTTTCAATTGATGTGAAATTCTCCCA G A 155 TGGATCAGTAGCAAAAAATATAGTACCATTAATTTGACTTTTTATTAATGCGTCATGCCnGAAAATGGTCCTCAGTTATGCAGGGATTCCATTGCTGGCTTTCCTCTGCATGCCCCCATA C T 156 GAGGAGAATACCAATTTGATAAAAGCTGTGTGTGCTGAAAAAGCCCAGAAATTGCTGTTnAGCAGATTGGAGCCCGATCGTTCCATTATTCCTGGGCTCTGCGTGTCCTCAGCTGATTCA T C 157 CTGATGAGAAATTGCCTGGTGTGGGGGAGCTGCTGGATTGCCAGTGAGGAAGAGGTCCCnACTGGAACGGATATGTGGACCCTCAGAGGAGCCCCAGGAAGCCCTTCACTGCAGCAAACA G A 158 TCAGCCTTTTCCCCAAGCAAGGGGAGCCGCAGGCGGCCAGCAGGACTGGGAATTCAACTnGCTGCCACCGTGACAGCAGGCGTGTTGGGGGAAGTCTCTTGGTGACAAGTAAGTGGGCAG T C 159 GGCCCATGTTCCCAATGCTGTTGTGTCCCAGAGAGGAGGGAGAGGCCCTTGGTCCCATGnTGATGACCTCTACATTCCACACCCGAGCTGTGCAGCAGGGGACCTGGCCACCCCCAGACC G A 160 GGTCTCGCTAGGGGGATAAATCCACTCCTTTACCAGCTGGTGACCCCAGGATCGCTCTGnTACCTGCTGCTGTGGAGAAGGGGGGTGGGCAGAGGGGCTGCTGCTGCTCCAGGTCCCCCT A G 161 TCTGGGTGGCTTGGCAGGTCCTTGCCCCTCTCTGGGCCTCATTTTCCCACCTGAACAGCnCCAAGTTCTCCTAAGCTCTAAGCATCTAGAACACCTCCATCTGTATCCTCCCAAGTGCTG G A 162 CAGCCCCCTCCAGGCAGGTGCCCTTGGGACGTGAGGTGTGGAGGCTCTGGGAGCATCTGnAAGGTTAGAGCTGGAGCCAGGAGGGGGGCCTCGTTCAGAGCTATCAATTAGGGGGCTGGC G T 163 TGAATGACCACACGGGGAAGCTACCAGGGGCGCTGGACCTTGTCTAGACTAATGGTTCCnAGTTTTTTTTGGAGGTCACGATCCTCTTGAGAATTGGACTGGTTGATGAAAACTGGGTTA C T 164 ACATACTTGAGTCAGACACTCACTTTATAAAAACACTAATGGATTTAATCCTTACAACAnGGGCATAGATGTAAACAACAGCTGATTCCCTTTGCTGTATAGCAGAAACTAACCACATTA A C 165 GTCCCTCTTTTTCCTCTGGGTCCTCTGCCCCTTTTGCCAACACATCAGCCCTCCAGTGCnCAGAGCATGGTCTGAAGAGCCTGAGGCTGCAGAGATGAAGGCAGCCTCCGATTGGATGGG A G 166 CCTCCTTTCACCCTGATGGAAACCCATCGCTGCCCTTCCTTCCACCCGTGAGACCCACCnTACCATCTCCCATCCTCCTGTGGGACGGACTCACCCAGCCCTAGGAGGAGAAGTGCCATG G A 167 AGCCTGCAAGAGCAAGCCTGTTCTCAGGCCTCTCCTCCACTGGATGCTAGGAGCTCCTCnCCATCCGCTGAGACCAAGGAGACAGCCAGGATTGGCCTACACACCATGAGGGACTAACCA C T 168 AGATTTGGGTGCATTTTGTCATTGGACCCTGCTCCCACGTCGTTCAGAGTCAGACCATGnAGGAGGCTACAAAATGCTGACGGAATGGGTGAACAGGAGCAGCAGTCATCACATCTCATG C A 169 GAGTTCTGAACAGTCTTCCCCCACCCGGAACTTCTTTCCAGTCTGCTCAGGCTCTGCAAnCACAGGGAAGAGGCAATCTTGAATTTCAAGTGTATTTCATTGAACTCATCTAATGATTGG G A 170 GTGCAGGTGAACAAGTTACCTAGAGACGTGCCCATCGCTTAGTGCTCAGGAACTGGGACnGGACCCCACGATGGTTGTTACCCATGTGATGGACAAGATTGAACACAGAACAAGCCTGGA G A 171 GGATATATATCCAGCAGTGGAAGTAGTTCTCTTTTTTAGGTTTTTGTGCCTCATGCTCTnTTCTAAGAAAGGGGTCCCTGCTCAGCCCAGCACTCAAGAGTTGAGTCAGGTAGTTGGATT C T 172 ACAAAAAAACCCGAAACCTGTTTGCCAGAAACTTATAGCCACCTGACCCCCGGATGACGnGGCATCTGGCCATCAGGGCTGTGTTCTGTTGGACCTCTGAGACCCCGTCTACAGGGCTCA T C 173 GGGGAACAGATGGAACCCCAGCCTGGTGTTGCTTCTTTATCTCAGAGCCTTCGGAGGGAnGTCAGCTGGCCATCGCCCTTAAACCAGCTGGATCCTGTCTGATGGGGTTGCCTACCGTGG G A 174 TCTGTCACCCCAGAAAGCTCCTACGTTCCCTCTTCCAGGCAGCCCTTCTACCCCAAAGAnATGAGTGTGTGCTTAGTCACTTCAGTCGTGTTCAACTCTTTGGGACCCCATGGACTGTAC T C 175 GGCAGCAGCGAAGGCAAGGCCCCCTTGATCGGAGGCAGAACTTCTCCGTACAGTAGCAAnGGGACCTCGGTGTATTACACGGTCACCAGTGGAGACCCCCCACTCCTGAAGTTCAAGGCC C T 176 CTGCTCCCCACAGCCTTGCCCATGCCTAGAGCCAGCTGTGTGAGCACCCAGGGGCCAAGnTAGAACACCAGGTAATTCTGCTCCTGGAATAATCCAAATCTATTTTGCTCTTGGATGGAA A G 177 TTTCAGTCAGGGATAAACCATTCCCATCAAGTCCCAGGGAAACTTTCCCTGTGGATCTCnTTGGTGTCGAGGGACAAGCTGGGGCCAAGGTCATTGAGTTATTCACTCTGTAGTTTATTG T C 178 GCAGTACCCAAGGTGGCGGGGGCTGGTAGGGTGTAGCAGACACCTTCCTCCAGAGCCATnATCAACTGCCACCTTGCTTGCTAACTGGCAGTGCCCAGCTTCCTGGCTGTTTGCCTGTGA A G 179 TCAGTTGTATTGACCTGTGGACCTAGCTACTCCACGTGTGTATATCTGTCCCAAAGACAnATCTGATACTTAAATTGCTAATTTTGTAATAACAGCCCATGAAACTTAGAGAAAACAATA A G 180 AAGTTTAAAGAGGAAAAAGAAAAAGTCCAGTCCACTGTGTACTTTATGCTGGAACAGTAnAGAGGAAACGCCACCATATGTGCCTGGCCCCTCACTCCTGGGGCCAGTGAAAAACTGGTT T C 181 TATCTTCTGTCCTGTTGGCTCCATCACTGCCCTTGTCACTCTTTAAACCTCTTCCTGTCnGTGACCTGTATGATCCTGAGCCTTGCTTGGCGTCCAAGACCTTCCATGCTCTTGCACACT T C 182 GGCCTCGGAAGCTTAGGCGTGCACAGTGGTCCCGAGGGATTCAGGGATCCGCCCCCGACnTGGGCAGAAATTCTCTGTGACCTCGTTACAGTCTCAGCCTCCCCGGGCCTCGTTTTCCTC C T 183 AATGACCTCACATTTCCAAACCTCAGATCCCTCATTTGCAAAATAATTTTTAAAATATCnGCTGAAACAAGAACCATCTGCTATTTCCTTTGTCAGTAATTTTAACCCAGGGTCATCCTG G T 184 AATAGAACTTATACAGTAGAGGTAAAAAAAAAAAAATCACTAAAAAAGCCCATAGAATAnGGCTTTCCAGATGTCTAGTGGTATGACCATACAGAAAATTTCTAAAAAGGAACTTGAAAA C T 185 TAGAACCAGAGCTCAAAGCTGTCCTTTCTCGTGTGTTTCACTGTTTCTCCCCACCGATCnACGTAGCTGTCTAAATATAGAAACTTAGCTATAAAAGACTTAAAAACAGGGACAAATAGT A C 186 TGTGAGTTCCCAGGTGAGAGTAAGAGGGCGAAGAAGAGGAGGGAATGGGCTGAAGTGGAnAAGAGAGGAGGAGTGTGTGAGAGTGGTGAATGGGGGGGCGTGGCTCAGGTAGTATTTTCA T C 187 ACGTTGTACTCGATTCAGGTTCTCAGGGCACCCCTGGATCCTGGTTTCCAGGAGCAGACnTGGACGTGTTTAGGGGAGATACCTGGGAAGGAAAGAAGACAGGCCTGGTGATCCCATGGG A G 188 AAAATTATAAGAATAAAAATATGATTTTTTGAATAATTATTTTGTTATCCTTAATCTGTnTTACGTATAGCCAATGCCTATCCCCCCACCCCCTGCTCTGCCAGTTTTATATTATTTTCA A G 189 GTTGCAGGGAGGAGGGCTCTAGAACGGTCCAAACTGGGCTTTACAAGACTGTCAACTCGnGTGGTATTGGTGATTTGAATCAATTGGTTCTCAGCCCTCTACATCTTAGCAGGAAGGCCT G A 190 CACTGGGACAAGAGACCCACTTTTCCTGGCCAGGGAATCTTTGCATGCTAAAGATAGGAnTTTGGTTTGCACGGGCTTTATTGCTTTTCTGTCTCTGCAAATAAAGCCAAAAATAGTAGT T C 191 ATCCTGCACGAGGCACATGCTGCGCCTCTGTGTCGCTGCTGCACCTTTTTCCCAGTGACnTTTGCAGCTCACCCTGGAGGGAACAGGTTGGCACACCACTGGAAAAACAACCAGACAGGC T C 192 CAGCTGACAGTAATGGGGTACAGCAGATCCAGCCTCTAGGTTTCCTCCACCAGTGCTTCnAGAGATCACAGCTCTGAGCAGGGCGCCACCTCCTCTGACCCTTAACAGTTTCCCAGATCC T C 193 TGGGAGGATTTTGTCTATAATCCTTCTCTAAATGATCCATAGACTTTCTGAATATACACnAAAAGGGTTTAATCTCTTCCTCCCTGTTTTTTTCCCTGACCCTTTTTATCTAGCTTCTTT G A 194 AGACACAGGAAAGGCCCGCAGCCCAGTTAAGTCATGTCTGAGGCGAGACCTGAAACCCAnGTGGGATTTTAGCGAGTCAGGAGGGGTGGAGTGATCCAGGAGTGTGTCGGCATGATAAAG G A 195 TGTTCTGTAATTATTCAGAACCTCATTCAGCGCTCGGTCATTCCTGTTACTCATGTAGTnTCGGCGTAAAGACAGGGGTCAAGCCCCCTTTTAGGTGCTGTGGGTATGTTTCCTCTTCGT A C 196 AGTAAAGGTTCGTGGAAAGAAAGAAGACATGAGGATCCAGAGACTCAGACTGGAAGTCAnAGTATCAGCTTTGTTAAACTTCAGATTGTCTAGCATTCCCTCTATTTCCAGAAGTTCAAA T C 197 CAGTCGATGGTTCAAGCACTGGAGTTACTCTATGCTCTGGGAGGTACGTCTGTCTCTTAnTCTGTGTTTCTTACGTATTTATTAGTATGTGATATTAGGTTGTATTCACTCTAGGGCTCT A C 198 GCGGTTCTCATTGATTTTATTTTGTCGGGAAAGTTGTTTCTCAAATTCTGTGTACCTTGnGGGAGGGGGCACAATGTAGCATGTGCCAGCATTTTTTTTAAGCCTGAAGGAGTTTTCATC A G 199 TGTCCTCACTCTCGGTATAGCTGTGCAGAGAGAGGAATCCAGGTCCCATTCCACAGCCCnACAGAGAACAGATGGACTCCAGTACCTGGGGAGAAAGGCTTCCGTAGAGGGATGTATTTG A G 200 CATGTCCCGATGCCACTAGCGAAAGCTCATCAGCTCGAAACCCATCCCAGATCCTCGGTnGCAGAAATTCACAACCGTTTAGAGGCTCTAAGCTTCTGTAGCTCAGGAACATAACTTGTC G A 201 CACTTCCCATTTCATTTTACTTCTGTTACTCCTTTCTCTTAGTTTGCTTAATTGGTGTCnGTGGTTGGCAAAAGGCCTAACTGTAGGTGTGAGAGCAGGAGAAAAGATGTTTGCAAGATG T C 202 AGTGGCACCATTTGTGCAGAAACACCTGTATATATGGAGCGGGAGTGAATTTGCTGGATnCTTGCAGTAAAGACAGTGAGGCCTCCTTCCTGCTCGCCCTCTCTCCCTCCCTCTCTCTTG A G 203 TATGCAGCTGTATTGTGCTAACACCTAACTGATGGTAACTAGCAACCCTGCATGGACACnTAGATAGCTGCACCCACAGTGAAAGCATATCCTTCAGATATACACATTGAGTGGGTAGCT T G 204 CATTTAAAAAAACAGTAGGTGTTCAGTTAACCCTCTGAAGGTGTGAAGGCATCTTCCTAnTCCTTCCCTACCCTGCAACTCACCTTGGGTGGTGCACACACCCCAGCATCAGTGCACGGG A G 205 CCTCAGTCTTCAGAACAGTTTCTCAGTAGAGGGATGCTGGAAAAGAATGGTGTTTATTTnAGAGGATGTCGGTGAAGGCAGTGGCTCCCGGGCTTACCTGCACAAGCGGGATCATTTGTG T C 206 ACTGTGCTAACCACATTGTGTCTATTAACTTACTTGATCTTGATGAAAGCTCCGCAGGAnGGAATGGAAGTTTGAAAAGGTCACCGCTTTCCAGGGATCACACTCCCTGGTTTATAACAG A G 207 ACCCCCTGAGGCCCAAATGGAGAGCTAACACTTCTATGAAGCTACTCCCTTCCTGAAACnGGGTGGAAGCCCTTCTTCTGTGGAATCTCAGAGCACTTTCTGTACCTTGTATATTTCATT A G 208 ACCCACGGTTTCAAAGACATGTAGAGACGTGAAGACACATAGATATACATATATGAACGnGCATTTCAAAACACACAGATTCACATGGATATGTGGACAGAATACAGACACACCCCCATT T C 209 GACTAGGGTCAGGGTCTGTGGGTGGGGACCACCCTCCCCTTCAGAGCTCAGGCAGGCTTnTGATGTCCTTGAGTGCTAGGGGAGTAGGTAAAACTGAGTTTTCTCATTTTTAGCAACCCA T G 210 ATGCAACAGGAATCCTAGGCCATGGCCGAGGTGGTTATCCCTTCATGGAATTCCCTTCCnGCCCTGATGTGCATCTGTGGAACCCCTGGCATCTGGATGTAGATGTCACCTCTTCCCTGA A G 211 CTTGGGATGGGGCAATAAGCACAGAGACCTCAGCTCTGGTCTGGGCTCCATCCTGACTCnTTTCTAGTCTGGTTTGAAGCCAGATAAGTCTTATTTCCTCTCCCTGAGCATCTCAAGCAG G A 212 GCATGGGAGGCATTGCAGCTTAGAAATCTATCTTTGCTTTCCTTTTTGCTGATAAGAACnTGAACTCTCTCCTGTTGGTCCCTCATGGAATGATAAGTGGTGGATCCATTCCCTCACAAC A G 213 GCAAATGACAGGGGATGTTACACAGGTTAGTATAATCCTCAGTGTGAAAATGATTTGAAnTCCAGATCCCAGGCAGGTATTTGGGACTGTGGATTTCTTCCCATGCTCTCTTTTCTGCTC C T 214 GCTTTACACAGAAAAACAAAACAAAAACAGAAAATAGAGATAACAGCTTCTATGGGTACnTCAAGTTCTCTTAGAACTGCATCAAGGGGGAAAAAAATTCTCACCAAATATTTGAGTTAG T C 215 ACCCTGAATCAGGAGTTCATTTACACAGATGTCTAGAAACTCCCGCACATCTACACACAnTCACTCACATTCTTTCTAAATACATGTTTTATCTTCCTTGTTATCAATGCTCTCCTAACG C T 216 CCACGAACTAGGACTCTGATTTGTGTTGGGGCTTCCCTTGTCCCTCATTTCTAAGGAGCnTCCTGTCTGGCAGGGCCGGGTTTAGGATTTGGAAATCAATGTCAGAATGGAAGGGCCGAG C T 217 TCCTCGCAGAGGCAGGACGAAGCCTCTCCAGGCATTTCTGAGTTGCCCTTCAGGGCAGCnCTTTTGTGATGTGAATGCAATGATGAAAGGCCCCAGATCTGTGGCTCTGGGTGGAATACC C T 218 ATTTCCATGGGGAAGGGACTTCCACATACTCTCTGCAGTTGTCTGCAAGTCTAAGAAAGnATGGAGGGAGGGAAGGGCTGGGGCCTCAGGCTAGAGCATGGTGCTGATGAAGTTCCAGCC G T 219 AAGGCCACGACTAGCTGAGACCCACTGCTGCCCCAGGCTCCCACGTACCTGTGAAGTAGnGGAGAAGATGCCGGGGTTCCACAGAGCCACCACTCCTCGGCCCAGTATCTAATGAGCCCT C T 220 GCCAGAGGCAGGGTCGGGCCCCGCACGTCCCTGTCCGTCTCCTCCATCACTATTACAGTnACGGCTCTGGGAGAGCACTCAGGCGTGAAAAAGCTCCTTAGAAACACTGGGAACTGAGGT G T 221 AGAAAAACATGAAAATGATCTAAGTTTTAAAATTTAAGAGAATTAAGCCATGTTAAAAAnGGAATGAGCAGACATCAAGAAGCCTGCTATTCAGGCCCCAGTTTATGATAGCTGATGCAC T C 222 AACTTTTTTTTTTTTAACACACACTAAAATGTAGTAGGCTGTGCACTTAAGATACCTACnTTCACTATATAATAGACTTTAGCATAGAGGAAGAATAGTCAAGTCACGAAAGCAATGCTC A G 223 ACAGAGGGAAACTGCTGGCTTTATTGGCTATGCTCTAGAGAAGATGAACTGATCCACCAnACAATCACAAGTGCTAAAATTATCAAGAACAATTATGTAAAGTTTAAAAATAAAATCAAA C A 224 TCAGAAGCCACAGCTGGCTCGTCAGTGCGCGAGTTTCTTCGGCTTGGAGTTTTGGACTTnTCAATTATCTCTTTGGGCTCACTGCTAACAGAGGGAAGCACAAAGTCCAAAGAGGTGAGG C T 225 CCACCTGCAAGTGGCTCAGATGCTATGCCAACATGATTGCTTTTTGTGGTCGGCGCCGCnGAGATGAGTTCAGAGGGTACCAGAGCGGTTACTATTGACCGTACATTGGTGGGGAGAGTA A G 226 CGGTGGCTCCAACAATCCATAACACCTTGCAAGAAATTGTAGACTGGCTAATGAAAATGnTAGTCAGAGAACAAAGAAAGCTGGAGAATACCAAAACAAAGCTAATTAATTTTGTTGCAG A G 227 AGCTGGGCAGTTAGAAATCTGGCATCAGAGAGAGAGCTGAATTCTATGATGCTCTGTGCnGGGAGTGCAGCCTCTTCAATTCTCAAAGGTTGGAGGTCAATACCTGACTGAGAAGCAGGG A G 228 ATCCTTTAAACACTGAACAGTACCTGGTGTACATAACAGGCACTCATTAGCTATTTACTnACTACATGATGAAAAGTCATCTTATCATAACCTTACAAAGAATCATAGGAGTTTTTCCAT T G 229 TCAAGGAAACAAAATCACATCTGATGGCCTCAAGGGTTGTGTTTTTGAAATGAATCTTGnTGATCTGCAGAATGATGAAGCTGCCTTTAGACAATTCAAGCTAATTACGGAGGATGTTCA T C 230 GAAAAGGGAATGGCAGGGATATCCATACAGAGGAGACACCAATGCGAAAGACCTGTGACnGGAAGAAGAAATGTATATTCAAGGAACCAAAAGAATGCTGAAGAGGCTAGAACAGACAGC G A 231 TTTCTTCCTGAGTGAGACTGCAGTCTGGTCTTAAGAAAATATACATAAATGTACTAATAnTCAACAGGTTCAATATCAGTAAAGGAGCTGGTTTTTGGCAATTTTTGTTGCCTCTTTGTG A T 232 GCAAGTTAAAAGAGAGCCTAGCAAAACACAGTTACAGAACCTCCTGAATGATTAAAGAGnTTAAAGTATGTTGGAAGGTAAGAAGAAAATAAGTAAAATGAGTTCAAAATGGTAAACAAG G A 233 CCAACGTAGTGGGTTATTGTCAAGATTTAAGTGAGATAACATGTGGAACATACCTAGCAnAGTGCCAGGTCCATGAAAACCCTCAATAAAGCTTATTATCTCCTTATCACGATCATCACG C T 234 GAAATGCAGATCTTCTTGAACTCACCCCAGTGATATTTCCATGATGCTACTTTATCCTCnCAAACCTACCAAATCAATTAATTTTTTTCTATTTCTGCCACAAGAAATAAAGCTGACTTA C A 235 CGACTTAGCAGCAGCAGTAGCAACAGCAGTAGCAGCTATATTGCTATAATATTGTTACCnATTTGTGACTCTATTGTTACACTCCCCAGAAGTAAACACAATGTATAAGTTTTTGAAAAC G A 236 AAGAAACAGTTAACAGCAAAAAGTACTTCATATATCCATCACCCAGGAAACACTGTTACnTTTTCTGACTTTTTCCATGTTGTTCTATGTGCTAAGTCACTTCAGTCATGTCCGGCTCTT C A 237 TACAGATGCTCCCTCTGGGCTTCTGTTTCACCACAAACTCCTCATGTAACCTCTCCCTGnCTAGCCCCTCCTCAATCTCCTTTGCCTGCCGCTACCATCTTCCTTCTGCATGTTTTTTAT C A 238 ACCCATTGAGCCATTGGGGAAGCCATTAACAAGTGAGGTATAAGTTAAATATTTAGTTCnCCACTATAATTTCATTTTACTGCATGCTGTATCATTGATTTATGTATTGCATATTTGCTA T C 239 AAAATTTTTGGTCAACCCAATACATGAAAGAGAGGTTTAGATTCTTTATTTAGTTTTGAnTAGCAACATGTAATTTTAACTGAAGCAGTTTTAAGTATAAAATTGCAGAAGAAATTTTAC C T 240 ATAAACCTTTTTAGATTTCATCACTGAGATTCCACCAACAACTTGGCATTTAATAATGGnATGCTATGTACTCACTGCAGATGGTGAATGCAGCCATGAAATTAAAAGACACTTACTCCT A G 241 CCATCTCACGGGGACGGGTGCCATCAGCTCAATGGGATCAGTCCCTGGCCTTCCTGGCCnCGGGTGCAGGCTGCAGATTGCCACCATGACCGTCCTAAAATACGGTGCACAGGAGAACGT T G 242 AGCTGTTTTCCAGAATTTAACACATCGTTTAACCAGACATATTCTTAGCAGCACTCAAGnCGTTCCGTGGAGTGGGTGTATTTGCAAATTCTGGTCACGCAGAGCTGATTCACAACCACA G A 243 CTCATCTGGGTCCCTCTTTGGGCTCAGAGTGAGTCTGGGGAGAGCATTCCTCAGGGTGCnGAGTTGGGGGGAGCATCTCAGGGCTGCCCAGGCCAGGGTGGGACAGAGAGCCCACTGTGG T C 244 TGTGGGGGGCGCTGGGGGCTGACCAGAAACCCCCCTCCTGCTGGAACTCACTTTCCTCCnGTCTTGATCTCTACCAGCCTTGAACGAGAACAAAGTCCTTGTGCTGGACACCGACTACAA T C 245 TTTCTCTCTAGTTGCAGTATGAGAACTTCTCTCATTGCGGAGTGCAGTCTCTAGAATGCnTGAGCTCAGTAGCTGCGTCGTGCAGGCTTAGATGTGGGATCTTTGTTCCCTGACCAGGGA A G 246 TATTTGTTGAGGTGTTTTTCGTAGGAGCTGTTCAACCTGAGTCCGAGGTCGTGGATGACnCCATTCAGGTACTCCTCCGCGAGGTTCAGGACCTCCTGGGGTGTGCCGCCCACAAATGCA G T 247 CACCAGCGATAACAGGTAAGACTTGTGGAGCCCCTTTCTGCGTGCCGGACGCCGTGGCTnCTGCGGTCTGGGTCGTGAGCATGTCGTGGACAATTTTTTTCAATCTTTAAAGAGGCATAA C T 248 GAGACAGTCCCCTGCGTGGCTGTCTTCCCCTTATGTTTGCAGACTCCAAAGAGCTGAGCnGACTCATTGGAAAAGATCCTGATGCTGGAAAAGATTGATGGCAGGATGATAAGGGGGCAA C T 249 GAGGTTGAAATTGAGAATGTATAGGCTGAATATAACTCAGAGTATTTTTTTAACTTTTTnTTTTATATTGGGGTATAGTTGATTAACAGTGTTGTGATTGTCTCACGTGAACAACAAAGA A G 250 GAATCCCCCAGGAATGGGATTATTCTGCCCAGAGGGCATTTGTGCCCAAGATCTCCAGGnACCCGGCATGGCCAATGCACAAAAAAGCAGCCTGTGTTCCCTTCAGGCTCCCTCAAACAA C T 251 GCCATGGCTGACTTGAGCATATTGGGGGACAGTGTTTCCATTCACCAAAATACCGAAAAnCAGGTTCGTGGGGACAGGAGGAGATGTGAAGTTCAAACAGTATAGCCACACCGTGTTTGA G A 252 CCTTCAATTCTGGAGTAGCCACTGTTGGTTGTGTACCAACATCCATTCTTTCCCTCTAAnTTACTAACAGAACCTGTTTGTTCAGTGTGTGATGAGCCCAAAGTAAGAATTTTCACCTCT C T 253 CAAGAATACAGTTGTATAAGAATACATAATTTTACACGGGGTTTCCTACATTCACGATTnTCTTTGGGAGGGCCATTTATGTGGTCAGGTGTGCCATTCATTCATTCACTGTGCTGCAGT G T 254 TTGCCATTCCCTTCTCCCGGAAAATCCATTTGTGTACCCTAACTCAGGCACACGGAGGCnCCAGGCCTAAGAGGAGCTGGGGGTGGGCAGGAGAAGGCACTCAGGGTGGGAGCAGGTCCC A G 255 CAACCTCAGGTATTTGGAAAATTAAATCTTTTGTGCAAAGAGGCATGTGGTGGTGGTGGnGGTTTGGTTGCTAAGTCGTGTCCAACTCTTGCAACCCAGTGGACTGTAGCCTGCCAGGCT C T 256 CCACACGTCCATTCTCTACATCTGTGTCTCTATTCCCGCCCTGAAAATAGATAGACATTnCTCCAAGAAAGATAGACAGATGGCCGAGAGACACAGGAAAAGATGCTCAATAACACTAAT T G 257 CACTAAACGCTTTGTGCCATGAGTAAGTTATACAGACACCACAGCACATGTGGAATAAGnCCGGCTCCTCCTCTCGTGGAAATGTCAATATCAAGTACTGAGCTTGACCAAGCAACACAA T C 258 CACCCTGAAGCGGGTAGGGAGGAGTTCTATAGTGCTCAGTGAGCAGGGTGTGGTCAGCTnATGCACAGTTCTAGGATTGGTTGCCATTGAACTGAAGTTTCCAGCGTCATCAAACTTCTG C T 259 TAATAGAACAATCTTCTTACTAGTCTTTGCCACCAGGAGATAATGAATGAGGAAATCCAnTGTGGGGGGCATAATGTTAGACACCTGAGAAATGAAAGAAATGTTTCCTGCTGTATCAGT C T 260 CTGTAGCACAAATCCCACCACCTTTTCCAGTGAGCTAACCCTGAATTCTTCACTCTGCCnTCCTTGGCTTTCCCCAGGAATGCCCATAAAGTCATGGCCTAACTTTCCCCTCACTGTTGT A G 261 GGAAACCCTTCAGAGCAGAGTCCTCGAAGGCATGGATTTCAGCTCTGAGGACAGGCACGnGCAAAGTGGGGTTTTAATTCCAGTGAGAACTTCCCCAAAGCAACACGTGCTGACTCCTGA C T 262 GCATATAAGGACTATGCAGACTTCACGGTGCTGGTGGTAGTGACAAGAACATTCAGATGnTGGCCCTTTCATAAGCCAACTCAGCTCTAAATGCTGACATTTCCAAGAATCATCCCCTTG C T 263 CATCATTGTAAGCACAGAAAGCAAATATTAAACAAAGGGAACCTACAGAAACAATCAGAnATCCTCTCCCTTTGTGATATCCATCACTTCAGAATAAATATTAATAAACAAACCTAAGGT G T 264 CAGCAGATTAGATGATGAGAGGAGAGAAGTTGGGGTACTGATACCCTGGCTTCTTCCTGnTGGTGATGGTGGCTGAGCTTCCTGCCCTGTGAGCATGGCTCCTGTGGTCCAGCCCTGTCC C A 265 TGAAACTTCTCTACTCAAACTTCATGCTGGTGCCTCTGTGGCAACTTTGGCCACCAAGGnTGGCTGAGGGGTAGGGAAGCTGGCATGGATTTAAAGGCCTCGAGACTAGGGGTGACCCCA C T 266 CGTGAGCCTCAGGGTAAGGTGGACATCTTATTCCACTTCATTCCACTCCCCCCCAGTTCnTGGATGGAAGGGAAGACCCATAATGGGTGTGAACATCAGTCTACAAAGTCATTATTTTCT G A 267 TGCACACACATACAGAAACTATTAACCAGTGAAGTTTCAGCTGCCAAACTGGGAATGATnTGCACAATACATTCCTGGATGTGATGGAGCTACACCCTGTGAGTATTTTGATCGGCAAGA G A 268 ATCTGAAGGCTTGACCAGGGCTGGAGGGTCCATTTTCAAGTTGGCTCTTCCATGCGACTnGCCAAATAGTGCTGGCTGTTGGCAGGAGACCTCAGCTCCTCGCCTTGTAGACCTGCCCAG A G 269 CAAAGACTGCCCATATGAAGGATTCCACACAGGACAGAAATGGCTGACCCTGTGCCCCCnCCACACTCAGGCACTGCCTGGGGGCTGCCTCTGCTGAAAAGCAGAGATGGAGACTAGATG A G 270 GCAGGTGGAGGCAGCAGGATGGGGAAAGGGAAACAAGGCTGGAGGGCTGAGTCTAGAAAnAAGTCTGGGGTCAAGGGGAAGGACCGGGGTGGCAGTGGAGAGTCTCAATTTGCTGTGCTA T C 271 TCTCTGTGGTTTTTCTACTCTCTTCTCTTCCTCAGAGTCCCCAGCACAGTTCTCTCAGCnGCATTGACCACTGGAGCCTGAGATGTTGGCAGATAGCCCTTTGCCAGCAGGTAGGATCCG A G 272 AGTGGGTGAGAGGGTTTGCCTGCAGGGGCGGCCTGGCCGCTGGGCTCTGGGGTTTTCTGnGCCCTCCTGAGGCGGCTGTGTTTGGCACTGACCATCGACGGAACTTATTTTCAGCAGGTT T C 273 TAGGGGCCCACCCACTCTCTACAGTGTTGACTAACCTGCTTAAGTGAAGTTGCTCAGTCnTGTCCGACTCTTCTCAACCCCATGGACTGCAGCCCACCAGGCTCCCCCATGGGATTTTCC A G 274 AGGTTATAGCCCGGCCTCTTCAGGGAGATGGTTGTTGATGTTTATTATCATCATTTTATnTCCATTTTACAGAAAACACACATGAGACTCGGGGCATTTAAAGAACTTGCCTGTGGTTAC C A 275 TGATGACAAAGGGATCTGGCTTTTAGGGTTTAAGAGTGCAGCATGATCCTCACAATCCTnGGGGCTTGGGATGAGGCCTTTGGACTCAGTGGAAGGGTGAGGACCTCAGGGACCCAGGTC T C 276 CAGGTGTAGCGGTACCATGCGTCCTTCTGGGCTGGCAACCCTAGAGCAGGGTCCAAGAAnCCTAAGCACAGGCTGCTGCCATGTCCCCTCCCTACCCATGTTCAAGGGCTCTCAGAGTAC C T 277 GATCCATGCTGCCCTGCGAACAGGGGAGAAGCACAACTTTCTTATTTGCAGGCTGCTGCnTTATATGTTTACCTGGCCCCAGAGAGGGCAAGTTGGTCCAGGCACTGAGATACCAGAGCA A G 278 CACTGCGCCTGTCCTCCATGCTGTTGACACCCTCACCTGCTGCATGATGGCGCCATTTTnATTGGACCCCAGGCCTTTTAACACCTGAGAGACCCTCTGCCTGGAGCCAGGAAACTGAGG C T 279 ATTCACAGTGATGCAATGACGATGATGCTTTAGCCTGAACCACAAATCACAGGTGACAAnGCAACATTAGCTAAAAATATATCTAATTTTTTCTGGGTTAGATTTACACCTATCGCATTT C T 280 TCTTGATGATAGCTCTTCTTACTGAATATGAGGTAAGATACCTCACTGTGGTTTCGTTTnGCATTTCTCTAATAATCAGTGATATGGAGTATCTTTTTATGTGTCTTTGGCCACCTGTGT C T 281 GTCTTTCCACTGTTTATAAGCAAATATACCCCCTATTTTTAGGTAACTGGTAGCATACTnTACTGGAGAAGGAAATGGCAACCCATTCCAGTGTTCTCGCCTGGAGAATCCTGTGGACAG A C 282 ATACTAGAACAGAAACTTCAGTGACCACACATGATGAGTAATATCATCTTTGCAAAAATnGTTTGGAAAAGTCACTAAGCAAATGGATGACTATATTCCTCAACAAGCAACAACAGCAAA A G 283 CACACTTTCTGTGCACTCTCTCACAGGTGCTGCCCTGAGACTCTTGGCCCTCTGTTCTCnCCCCACCGCCCTGTCCTAGACCATTGGACCCACGCCATCAGACTTCACTTACCACAAGAT C T 284 AAAGAAAAAACTAGAACATTTTCATGAGCCTGGGTCCTGCCACTTTGGGCATGTTTGCCnGTCATTTGCCCCGCCACCCCACACACCTTTAACCACCTACCTCACAGACACCCAGCGGCC C T 285 TCCTTTGTCACTCAGCCGGCTAGTCACTGCTAACTGGATGACTCTTCTCTTTCCAGGCCnCCAGTCCTCGCTCTGTGGAGGCAGAGCCTGGGTCTCACCTTTACTGTCTTGTCCCCAGCT C T 286 CAAACACAATCCCACCCGATGCGGTTTTGATTCTTGGCGCAGAATAAGCGCCCTCGGCGnTGGGATTTATGCTTCACTCGCAGTCCTCCGACCTCGGACTCTGCCCAGATGCCGGGAACT T G 287 CCGCCGCAAACCAAACTCCGCACCCTTTAACCCTGTGTACCACCAAGTTGGGCTCTGGGnGTGATGTTGGGGGGAGAGTGGACAAGGAGAGAGGGGTGGGAGGCAGCACAGTCCCTCCAT T C 288 AAATATTTCGTATTAGTGGCTGCTTCTCTTTTCTAAATGAAGGCGGCCCCTTCTGAGGGnGTAAGAGGAGGGTTGGAGTGAAGGTGAATACCTGCCAGGTCCTTCAGGGGAGAGCCAACC T G 289 TCTGGCTCCAAGAGACATGTCCTGGCCCCTACTTCCTCACACACTTGGTGTTGGCTTGGnGTGCTACAGGTGTTGTACCTGGGCTGGTGGGAGGGATGGGTAGATATTTCTTCTTGGGTA C T 290 GGGCATAGAGAGAAAACAAATGCCTCTTTTTTGTTGTTTTTATTAATGAGCCTCCCTACnCAAATTTTTCTTTTTGTATTTTACTGCCAGGCTGGCAATTACAAGAAGACATTTGTCTCC G A 291 GACGCCACAGATGTCCTTCTCCCCAAGGGAACAGTGGGCAATTGGAAGCGCCCCCAGGAnGGTAGGAATGTTATTCTGACAAAATCGCTCTTTCTGCAGGAGGAGCTGTGCCAGTCGATA T C 292 TGGAGAACCACTAAACATTTCCACAGTGGCTGAGCACTTTCCACTCCCAGAAGGTGCACnAGGGCCCCCGTGTCTCACGTCCTCACCAGCAGCAACTGCTTTCTGTCTTTTTGACTCTAG G A 293 AAAGGCCTCAGATACTGCAGCTGTTGGAGGAGAGGTGGGTGCCCTCTGGTGCTCTGCATnCTGTGCCGGGACTTGTCTGGGGTGCAGTCTTGGCCAGTGGGGAGCCTCCCCTCCCTCCCT T C 294 TGAAGGGCCTCGAAGGGAGAATACGCAGCCCAGGACGCTGTCTGGCCCAGTGAACACGAnGGGGGCCACTGTGCCTTGGCAGAGGCAAACATGTGAGGAGTGTCTTTAGGGGCTGGTGAG G T 295 GACACCACTTCCAAGGGATCAGCTAGCTTCCTTTGCCAACATTGGGACAGAGGGACATCnTGAGCCAATGGACAGGAGAGGGATAGCCTCACTCCTGACTCCCAAGTATGAGATTTTGGA G A 296 GCTGTGCGACTTTCCAAAGGGGTCGTCATGTCAGCCGCCTGGGGCCTGTGCAGCCCCATnTGCGAATTCCCACTCCAGGTCTCCCACCAGTCCTGGTCCTGTGCCCTTGAGAGACCCTGA G A 297 ATAATTGGAGCCTGTGATGTTTTCTTAATCCAGTACACAGCTGGGATTCTTTAGAGTGTnGGTTATCAGGATCTTAACATCTGACCATTTTGGAAGACTTTATTTTGGAGGGCAAGTAAT T C 298 CCAGTTCTAACTGTTGCTTCTTGACCTGCATAGTCCTGTAAAGCAAATAGTCCAAGTCCnCTCCTGTTGCCTCTTGACATGCAAGTCAGATAAAGCAGAAGAGAGGAAACCTTTTTATAG G A 299 CGCAATCCATGTTGCCAGTCAAATCTAAGTAGAAACAAGAAGACACCCTTTGAACCTACnCAAATTATTATATTGCCAGGAAAGGAAGAATACTCAACAAGAGTTAACAAGTTCTGGAGG G A 300 GAAAGAAGAAATGCAGGATCACTGAGGCCTAGGCACCCTGGGCTGGGCCTCACCTGGGCnGGTCTGCTGGAACCCGATAGGCTTTGTTCCAGACTCCTCTCATGTGTGTGCGTGTGCACA G A 301 TCGTGCAAAGACAGTTGTTGCCGGTATTTAGGGAGGGCTGCCCACACTTAGAGCGTCTGnTATAGCTCCAGGGTCCTTGGCCTGGGCCTGGCCACGCGCATCAGGGCTGCTGTGCCGCTG C A 302 GCTGGCCATGTGGATCTTTGTTGCAGGGCTTTCTGAGCTGCTGTTCTCAGACCCTTGAGnGGGCCAGATGGAGGAGGGAGTTCATGAAGCCAGGGTTGGGAAGCAGCTGGGTCTCCAGCG C T 303 CTGGCACGTAGACTCCAGTCCACACCTCATCTTTGCCAGCTCCCTGTCTCCGTGCAGGAnCTCCCAGGGGGCCTGGAGTCCAGGCCCACAAACTGAGGCTAGGACAGCCCACCTTGAATG C T 304 GTTTCTCCCTGGTCACAAGAAGTTCTACGCAACTGGCCCAGCATGGAGGAAGTGTTAGCnTAGCTCGGGGTGTTTGAGAGAGAGGAGGTCCTGGGGGTTACAGAGCGGGGCTGGGAAATG A G 305 GAGAGGGATGATTCTGGGGTAATCGCTCTTCCTGTCTCTGGGTGAGCTCAGCTCCAGGAnGCATTGGGACCAGCCGGCAGCGGCAGGGGTGGCCAGGGAGTGTGGACCTCCGGTCGCCAC A G 306 CTGAGCTGTTCCCCTGCTTTGAACCAACTGTCACCATCTCATCTCAGCTCATTTTTAGGnATCAAGTCTACAACTGTGCCACAGGACCTCTAGGCAATTTGGGAAGAAAAACCAGAATGG T C 307 CTTCCACTCTCTCTCAGTCAGTTCTCATTGTCTGCAGGGGGCATGTTCTCTCAAGTCGCnAGGACCCCTGAATTAGCCAGGCCTGGACCACTGCTCCCCAGCAAAGTGCTGCTCAGGGTT T C 308 TGGCGAACGACTTTGCGAACGATCTGGAAAAGTGAGAGGGAGGGTAGGAGGGGGCTTGGnGAAGCCGTCGAGGAAGAGCTTGAAAGGGGGCAGGTCCCAGAGGGTGGTGCAGTGGGTGCG A G 309 CCGCCCCAGCTGAGCTCAGGCTGTATCAGGCAAAGTAAGGACCGCCACGTCTGGAACTGnAGCAGGTACCCGAACCGTCCCATCTGAGCCGGGCTTACCCTGCTGTTAGGGTAGTAAGAA T C 310 TAAAGGGCGTTTTGAACAACGCTGCCCCCACCCCCACCACCGAGAGCCCGCCCCTATGCnAGCCAGAGGCAGCTTTAGCTGTGCCCAGGAAAAGGGTCCCATTTAGGACTCGGGAAAAAA C T 311 TGACCGCACACCGTCCTTTGGCTTTATTCTTTGTGTGTGCATACGTGCTCCGTTGTGTCnGACTCTTTGCAGCCCCAAGGACTGCGGCCTGCCAGGCTCCTCTGTCCATGGAATTCTCC T C 312 GTCCTTTGGCTTTATTCTTTGTGTGTGCATACGTGCTCCGTTGTGTCCGACTCTTTGCAnCCCCAAGGACTGCGGCCTGCCAGGCTCCTCTGTCCATGGAATTCTCCAGGCAAGAAGAC C G 313 ATTCTTTGTGTGTGCATACGTGCTCCGTTGTGTCCGACTCTTTGCAGCCCCAAGGACTGnGGCCTGCCAGGCTCCTCTGTCCATGGAATTCTCCAGGCAAGAAGACTGGAGTGGGTTGC C T 314 CCCACATCTCTTTCATCTCCTACATTGGTAGGCAGATTCTTTAGCACTGAGCCGCCTGGnAAGCTGAAGAAAACTACACCAGGACATGAATAGCAAATTATTAAAAACCAGCAACAGAG A G 315 AGCACTGAGCCGCCTGGGAAGCTGAAGAAAACTACACCAGGACATGAATAGCAAATTATnAAAACCAGCAACAGAGAAAAAATTCAGGGGAAAAAAAGGAACAAAGTTAAGGATGGCAG TA T 316 TTTTAAGAATGATTTTTGCTGGAAATTGTGGTTTTATACATTCCATTAGGTTAAAGAAAnCCTTCTGTTTCTATTTAAATAAAAGGTTTTGTTTTGGCTTGCTTTTAACCAAGAATTGC GC G 317 AAATTGCATTAATACGTTTTATAACATCAGATGATCCTTGCATTGTTGGGGAAAAAACAnTCACGATGGATTGTTATCCAGTGCTGATTTGATTTTCTACTCACGCCCTGGGGTGCATT A G 318 TGCATTAATACGTTTTATAACATCAGATGATCCTTGCATTGTTGGGGAAAAAACAGTCAnGATGGATTGTTATCCAGTGCTGATTTGATTTTCTACTCACGCCCTGGGGTGCATTTACC T C 319 GTGACAGAGCTCGAGTCAAACATATTAGAAGTAATATCATATGGATGTCAATTTAAAGAnGTGCCATATTCTTTTTTACCAGCCTCTGGTTCTTTCCACAGAAGGAATTACTGCAGGAG C T 320 TCAAACATATTAGAAGTAATATCATATGGATGTCAATTTAAAGATGTGCCATATTCTTTnTTACCAGCCTCTGGTTCTTTCCACAGAAGGAATTACTGCAGGAGCTATTAAACTAAAGA A T 321 TAAAGATGTGCCATATTCTTTTTTACCAGCCTCTGGTTCTTTCCACAGAAGGAATTACTnCAGGAGCTATTAAACTAAAGACACCGCTACTGCTATATAAATGTTCCGTAGTTATTAAA T G 322 TAAACTAAAGACACCGCTACTGCTATATAAATGTTCCGTAGTTATTAAAATAATTATACnTTTAATAGTTGCATTATTCAGTTCAGTTCAGTTCAGTCGCTCAGTCATATCCAACTCTT T G 323 TTATACGTTTAATAGTTGCATTATTCAGTTCAGTTCAGTTCAGTCGCTCAGTCATATCCnACTCTTTGCAACCCCATGGACCGCAGCATGCCAGGCCTCCCTGTCCATCACCAACTCCC C A 324 ACTCTTTGCAACCCCATGGACCGCAGCATGCCAGGCCTCCCTGTCCATCACCAACTCCCnGAGTTTATCCAAGCTCATGTCCATTGAGTCGGTGATGCCATCCAACCATCTCATCTTCT A G 325 AGTTCTTTGCATCAGGTGGCCAGAGTATTGGAGTTTCAGCTTCAACATCAGTCCCTCCAnTGAATATTCAGGGCTTGTTTCCTTTAGGATGGACTGGTTAGATCTCCTTGCAGTCCAAA G A 326 AGGTGGCCAGAGTATTGGAGTTTCAGCTTCAACATCAGTCCCTCCAATGAATATTCAGGnCTTGTTTCCTTTAGGATGGACTGGTTAGATCTCCTTGCAGTCCAAAGGACTCTCAAGAG A G 327 GGTTAGATCTCCTTGCAGTCCAAAGGACTCTCAAGAGTCTTCTCCAACACCACAGTTTCnAAAGCATCAATTCTTCAGCACTTAGCTTTCTTCACAGTCCAACTCTCACATCCATACAT C A 328 ACACCACAGTTTCAAAAGCATCAATTCTTCAGCACTTAGCTTTCTTCACAGTCCAACTCnCACATCCATACATGACTACTGGAAAAACCATAGCCTTGACTAGATGGACCTTTGTTGAC G T 329 TCAATTCTTCAGCACTTAGCTTTCTTCACAGTCCAACTCTCACATCCATACATGACTACnGGAAAAACCATAGCCTTGACTAGATGGACCTTTGTTGACAAAGTATTGTCTCTGTGTTT A T 330 CTACTGGAAAAACCATAGCCTTGACTAGATGGACCTTTGTTGACAAAGTATTGTCTCTGnGTTTTTAATATGCTGTCTAAGTTGGTCATAACTTTTCTTCCAAGGAGTAAGTGTCTTTT C T 331 ATTGTCTCTGTGTTTTTAATATGCTGTCTAAGTTGGTCATAACTTTTCTTCCAAGGAGTnAGTGTCTTTTAATTTTATGGCTGCAGTCACCATCTGCAGTGATTTTAGAGCCCCCCAAA G A 332 GTCTCTGTGTTTTTAATATGCTGTCTAAGTTGGTCATAACTTTTCTTCCAAGGAGTAAGnGTCTTTTAATTTTATGGCTGCAGTCACCATCTGCAGTGATTTTAGAGCCCCCCAAAATA C T 333 AGTAAGTGTCTTTTAATTTTATGGCTGCAGTCACCATCTGCAGTGATTTTAGAGCCCCCnAAAATAAAGTCAGCCACTGTTTCCACTGTTTCCCCAACTATTTGCCGTGAAGTGATGGG A C 334 TAGAGCCCCCCAAAATAAAGTCAGCCACTGTTTCCACTGTTTCCCCAACTATTTGCCGTnAAGTGATGGGACCGGATGCCATGATCTTAGTTTCCTGAATGTTGAGCTTTAAGCCAACT C G 335 GATGGGACCGGATGCCATGATCTTAGTTTCCTGAATGTTGAGCTTTAAGCCAACTTTTTnACTCTCCTCTTTCACTTTCATCAAGAGGCTCTTTAGTTCCTCTTCACTTTCTGCCATAA G C 336 ATGGGACCGGATGCCATGATCTTAGTTTCCTGAATGTTGAGCTTTAAGCCAACTTTTTCnCTCTCCTCTTTCACTTTCATCAAGAGGCTCTTTAGTTCCTCTTCACTTTCTGCCATAAG G A 337 ACCGGATGCCATGATCTTAGTTTCCTGAATGTTGAGCTTTAAGCCAACTTTTTCACTCTnCTCTTTCACTTTCATCAAGAGGCTCTTTAGTTCCTCTTCACTTTCTGCCATAAGTGTGG A C 338 ATCTTAGTTTCCTGAATGTTGAGCTTTAAGCCAACTTTTTCACTCTCCTCTTTCACTTTnATCAAGAGGCTCTTTAGTTCCTCTTCACTTTCTGCCATAAGTGTGGTGTCATCTGCATA T C 339 CTTAGTTTCCTGAATGTTGAGCTTTAAGCCAACTTTTTCACTCTCCTCTTTCACTTTCAnCAAGAGGCTCTTTAGTTCCTCTTCACTTTCTGCCATAAGTGTGGTGTCATCTGCATATC G T 340 AGCTTTAAGCCAACTTTTTCACTCTCCTCTTTCACTTTCATCAAGAGGCTCTTTAGTTCnTCTTCACTTTCTGCCATAAGTGTGGTGTCATCTGCATATCTGAGGTTATTGATATTTCT T C 341 CTCTCCTCTTTCACTTTCATCAAGAGGCTCTTTAGTTCCTCTTCACTTTCTGCCATAAGnGTGGTGTCATCTGCATATCTGAGGTTATTGATATTTCTCCCGGCAATCTTGATTCTAGC G T 342 TCTCCTCTTTCACTTTCATCAAGAGGCTCTTTAGTTCCTCTTCACTTTCTGCCATAAGTnTGGTGTCATCTGCATATCTGAGGTTATTGATATTTCTCCCGGCAATCTTGATTCTAGCC A G 343 GCCCAGCGTTTCTCATGATGTACTCTGCATATAAGTTAAATAAGCAGGGTGACAATATAnAGCCTTGACGTACTCCTTTTCCTATTTGGAACCAATCTGTTGTTCCATGTCCAGTTCTA C T 344 TCTCATGATGTACTCTGCATATAAGTTAAATAAGCAGGGTGACAATATATAGCCTTGACnTACTCCTTTTCCTATTTGGAACCAATCTGTTGTTCCATGTCCAGTTCTAACTGCTGCTT A G 345 TTAAATAAGCAGGGTGACAATATATAGCCTTGACGTACTCCTTTTCCTATTTGGAACCAnTCTGTTGTTCCATGTCCAGTTCTAACTGCTGCTTCCTGACCTGCATACAGGTTTCTCAA A G 346 TTTTTCTGGAACTCTCTTGCTTTTTCGATGATCCAGCAGATGTTGGCAATTTGATCTCTnGTTCCTCTGCCTTTTCTAAAACCAGGTTGAACATCTGGAAGTTCACAGTTCACGTATTG G T 347 TTCCAGAATTTAACACATCGTTTAACCAGACATATTCTTAGCAGCACTCAAGACGTTCCnTGGAGTGGGTGTATTTGCAAATTCTGGTCACGCAGAGCTGATTCACAACCACATTTCTT A G 348 CACGCAGAGCTGATTCACAACCACATTTCTTGCTCTGTGGCACCAGTCTTTTCCCCCAGnCTCTCTTCTGAGCTTCGTGTTATCCTTTGCTGAATTTCCCAAGGAGAAGGCGGAGAATC T C 349 TCTTGCTCTGTGGCACCAGTCTTTTCCCCCAGCCTCTCTTCTGAGCTTCGTGTTATCCTnTGCTGAATTTCCCAAGGAGAAGGCGGAGAATCTGGCTTCAGAATGTGTGTTTCCCTCAA C T 350 AGAATGTGTGTTTCCCTCAAAGAGACACCAAGCAGACCTTGCATGAGGACTGTCTCAGCnGAGATACCCGTCCTGCCCCTGGCCGTGTTTCTGGGGTTTGGGCCATAGACCCCGCAGGG C T 351 TCAAAGAGACACCAAGCAGACCTTGCATGAGGACTGTCTCAGCTGAGATACCCGTCCTGnCCCTGGCCGTGTTTCTGGGGTTTGGGCCATAGACCCCGCAGGGCAGACGGGGGGCTCTG T C 352 TGCATGAGGACTGTCTCAGCTGAGATACCCGTCCTGCCCCTGGCCGTGTTTCTGGGGTTnGGGCCATAGACCCCGCAGGGCAGACGGGGGGCTCTGGCCCTGGGCTCACCTTTGTTCCC A T 353 AAACCAAACTTGGATGCTCTCACTCACACGCAGTAAAGCCAGTCTCCTGACGCCAGGGTnGTGGTGAAGAAAAGGGCAGTGTTTCCTGGGTTGGGAATATTCCCTGGAGAAGGAAATGG T C 354 ATTCCCTGGAGAAGGAAATGGCAATCCACTCCAGCACTCTTGCCTGGAAAATCCCATGGnCGGAGGAACCTGGTAGGCTGCAGTCCACGGGGTCGCAAAGAGTCGGACACGACTGAGCG A G 355 GAAGGAAATGGCAATCCACTCCAGCACTCTTGCCTGGAAAATCCCATGGGCGGAGGAACnTGGTAGGCTGCAGTCCACGGGGTCGCAAAGAGTCGGACACGACTGAGCGACTTCAATTT T C 356 GGGCGGAGGAACCTGGTAGGCTGCAGTCCACGGGGTCGCAAAGAGTCGGACACGACTGAnCGACTTCAATTTCACTTTTACTTTACTGCAGGTGCCAAGCAAGGAGTCCAAGTGCTCAG A G 357 TGGGCTACAGGTTATGTGGGCTACAGGGTATCTGATCAGCTTGTGGACATTCTTCTTATnGGTTAACGTTGAGGTCATCGGGGGTCACCGTGGTCAGCCTTCTAGTTCCACCTGATCTG T C 358 TCCACCTGATCTGGGGTCCACCTGGTCTGTGGGCAGCATATAGTTACCTTCTTCCACCTnGTGTGGGGGGTGGTTCTCAGTATCTGCAGAAAAACTCACAGGACATGGCTCAGGATATT G GGT 359 GGTCCACCTGGTCTGTGGGCAGCATATAGTTACCTTCTTCCACCTGGTGTGGGGGGTGGnTCTCAGTATCTGCAGAAAAACTCACAGGACATGGCTCAGGATATTCTCCATAGCCCTGG G T 360 CCATAGCCCTGGTTTAGTCGCTAAGTCGTGTCTCACTCTTTTGTGACCCCATGGACTGTnGCCCACCAGGCTCCTCTGTCCATGGGATTCTCCAGGCAAGAATACTGGAGTGGGTTGCC A G 361 CTTTTGTGACCCCATGGACTGTGGCCCACCAGGCTCCTCTGTCCATGGGATTCTCCAGGnAAGAATACTGGAGTGGGTTGCCATAGCCCTTGAGGAGGAATTAAATGTCCTGGACTTTG G C 362 CACCAGGCTCCTCTGTCCATGGGATTCTCCAGGCAAGAATACTGGAGTGGGTTGCCATAnCCCTTGAGGAGGAATTAAATGTCCTGGACTTTGCTTAATGGCTAAGCTATTGCTGTATT A G 363 GGCTCCTCTGTCCATGGGATTCTCCAGGCAAGAATACTGGAGTGGGTTGCCATAGCCCTnGAGGAGGAATTAAATGTCCTGGACTTTGCTTAATGGCTAAGCTATTGCTGTATTTACTT A T 364 CTCTTTGGAAGTGCGTGAAAGCTTAGGAGGCTAAAGCTTTTTTACAGACAAGAGGCAGGnGTAGGACATGGGGTGGGGGAAAAGCCTGTTTTGGGGAGACCCCATGGGGTCCTGCTCAG A T 365 CTTTGGAAGTGCGTGAAAGCTTAGGAGGCTAAAGCTTTTTTACAGACAAGAGGCAGGTGnAGGACATGGGGTGGGGGAAAAGCCTGTTTTGGGGAGACCCCATGGGGTCCTGCTCAGTT G T 366 GGAAAAGCCTGTTTTGGGGAGACCCCATGGGGTCCTGCTCAGTTTCACTAGGACATTGGnGAGGGCAGTGACTCCTCCCTGCCCCAGGACATCGCTGACCATATTTTTCCTGATTTATT C A 367 ATCGCTGACCATATTTTTCCTGATTTATTTGAACTATAGTCCTGTAAACAAACCTTCATnAAAACTCAATCATGCATCCTCCTAACTCACGCACTCCTGCGTCTAGTCTGTCCACAAAC C T 368 AACAAACCTTCATTAAAACTCAATCATGCATCCTCCTAACTCACGCACTCCTGCGTCTAnTCTGTCCACAAACACGGACCCTGCTGGGAGATGAATGAGCTCATAGCCCTGACCTGGAG T G 369 CCTGGAGCAATTCTATCTCATCTCCCTTTTTTTATGTGTTTTCTCTCAGCAGCCCCACCnTGCTTTTAAGAAATTAGGAGACAAAGAAGGAGTGATGACTCTCTAAGCCGCTCAGTCTA G A 370 TCCCTACTAGTTAGATCCAGTCCAAACCATGTGTGTTGAGGCACGTGTGTTGCGGTGAAnTTCAGGAGGCCATTCTGACAATTAGCACAGTTGCCCAGGAAACAGCAGTGTTCTGGACG C G 371 GTATTGCAGTCCAGGTAACACGCCTGTCTCATCTGTGCCCTCTTAGCCACTTCTTCCGCnACACTCAGGACCAGGATCTCACCTGCTGCTTAGCTGCTCAGGCTTCAGCATGTGCAGCA G C 372 TATCTTAAATATCTTTACTAAGATAATCTTCTCAAAAATCTCCAAAGGCTCCTTATTGTnTAGTGAATTAAGTAAAATGTTTCTCTGACTTTTTGAGATTTCCAAATACGTAAACCTAG T C 373 AAAGTAGTCTGGTTGGATTCTTTTGCATGCAGCTGAAGAGTTTTCCTTACGAACAAAGCnAGTGGAGGTGATGGAACCCCACTTGAGCTACTTCAAATCCTGAAAGATGATGCTGTGAG A G 374 CAAAATTCTCCAAGCCAGGCTTCAGCAATATGTGATCCGTGAACTTCCAGATGTTCAAGnTGGTTTTAGAAAAGGCAGAGGAACCAGAGATCAAATTGCCAACATCTGCTGGATCATGG C A 375 AAAAGGCAGAGGAACCAGAGATCAAATTGCCAACATCTGCTGGATCATGGAAAAAGCAAnAGAGTTCCAGAAAAACATCTACTTCTGCTTTATTGACTATGCCAAAGCCTTTGACTGTG C G 376 AGAGTTCCAGAAAAACATCTACTTCTGCTTTATTGACTATGCCAAAGCCTTTGACTGTGnGGATCACAATAAACTCTGGAAAATTCTGAAAGAGATGGGAATACCAGACCTCCTGATCT C T 377 ATCTACTTCTGCTTTATTGACTATGCCAAAGCCTTTGACTGTGTGGATCACAATAAACTnTGGAAAATTCTGAAAGAGATGGGAATACCAGACCTCCTGATCTGCTTCTTGAGAAACCT G C 378 ATCACAATAAACTCTGGAAAATTCTGAAAGAGATGGGAATACCAGACCTCCTGATCTGCnTCTTGAGAAACCTGTATGCAGGTCATAAAGCAACAGTTAGAACTGGACGTGGAACAACA C T 379 TGCAGCCATGAAATTAAAAGACACTTACTCCTTGGAAGGAAAGTTATGACCAAACTAGAnAGCATATTGAAAAGCAGAGACATTACTTTGTCAACAAAGGTCTGTCTAGTCAAGGCTAT C T 380 TTATGACCAAACTAGATAGCATATTGAAAAGCAGAGACATTACTTTGTCAACAAAGGTCnGTCTAGTCAAGGCTATGGTTTTTCCAGTGGTCATGTATGGATGTGAGAGTAGGACTATA C T 381 GGAGTTGGTGATGGACAGGGAGGCCTGGCATGCTGCAGTTCATGGGGTCACAAAGAATCnGACATGACTGAATGACTGAACTGAAGAGTTTTCCCAGCACCATTTATTGAAGAGACTGT G A 382 GGTATATCAGTATAGTCAGTATAGATCAGTATAGATCAGTGTCAGTATAGTCACTTTAAnAATATTAACTCTTCCAATCTGTGAGCATGATATATTTTCCCCTCTATATCATCTTCAAT T C 383 GGTTAGAGTCATTCCTCGGTATTTTATTCCTTCTGGTACAATTGTGAATGAGATAATTTnCTTAGTTTCTCTTTCTGATAGCTCATTGTTAGTGTATAGAGAAGCAACAGATTTCTATG C T 384 TATCCTGCTATTTTACTGAATTCACTTATTAGCTTTTTGGTGACATCTAAAGATTTTCTnAAGAAAATGGCATGGTATGGTATGACAAGCTGTCAAGCCACCTGCAAACAGTGGTGGTT C T 385 CGGATTTCTTTTATTTCTTTTTGTCTGAGTACTGTGACTAGGATTCCCAGTACTGTATTnAATGAAAGTGGCAAGAGTGTACTTCCTTGCCTTATTTTTCTGGTCTTAGAGGAAATGCT C G 386 TTTCTTTTATTTCTTTTTGTCTGAGTACTGTGACTAGGATTCCCAGTACTGTATTGAATnAAAGTGGCAAGAGTGTACTTCCTTGCCTTATTTTTCTGGTCTTAGAGGAAATGCTCTCA A G 387 TTTTTGTCTGAGTACTGTGACTAGGATTCCCAGTACTGTATTGAATGAAAGTGGCAAGAnTGTACTTCCTTGCCTTATTTTTCTGGTCTTAGAGGAAATGCTCTCAGGTTTTCACCATC A G 388 TTGTCTGAGTACTGTGACTAGGATTCCCAGTACTGTATTGAATGAAAGTGGCAAGAGTGnACTTCCTTGCCTTATTTTTCTGGTCTTAGAGGAAATGCTCTCAGGTTTTCACCATCAAT C T 389 ATTATGATGTTTGCTATGGGCTTGTCATATGTGGCCTTTATTATATGGAGGTTTATTCCnTCTATACCCACTTTGTTGAGAGTTTGTATCATAAAAGTATGTTGAATTTTGTCAAATGG T C 390 TGCTATGGGCTTGTCATATGTGGCCTTTATTATATGGAGGTTTATTCCCTCTATACCCAnTTTGTTGAGAGTTTGTATCATAAAAGTATGTTGAATTTTGTCAAATGGTTTTCCTGCAT T C 391 CCCTCTATACCCACTTTGTTGAGAGTTTGTATCATAAAAGTATGTTGAATTTTGTCAAAnGGTTTTCCTGCATCTATTGAGATGATGTTTATTTTTCAATTCATTAATGATTTTTATTC A T 392 TGTATCATAAAAGTATGTTGAATTTTGTCAAATGGTTTTCCTGCATCTATTGAGATGATnTTTATTTTTCAATTCATTAATGATTTTTATTCTTCAATTTGTTAATGTGGTATATCCCA T G 393 CAATGATATTGACCTAAGGTTTTTTTTTTTTTTTTTGTAAAGTTTTTGTCTGGTTTTAGnATCAGGGTGATGCTGGCCTCATAGAGAGAGTTTAGAAGCATTTCCTTCTCTTTGATTTT T A 394 GTCTGGTTTTAGAATCAGGGTGATGCTGGCCTCATAGAGAGAGTTTAGAAGCATTTCCTnCTCTTTGATTTTTTGGAATAGTTTGAGTAGGATAGGTATTAACTCTTCTTTAAAGGTCT C T 395 CACCCACTGTGTGCCCACGGGCCACAGCCAGAGAAAACCCACAGACGGCAATGAAGTCCnAGCACAACCAGAAAAAGAAGTTCGGTAGATACAGCTGTGAAGCCCTCTGGTCCTGGACT T C 396 CATATTTTCTATTTCTTCCTGGCTCAGTCTTGGGTTTGTACATGTCTAGGAATGTATCCnTTTCTTCTGGGTTGTCCCTTTTATTAGACATGTGTGGGGGCACACAGCACCGACCAGTG A G 397 CATGTGTGGGGGCACACAGCACCGACCAGTGAGACTCATACCGGCTTCCTGGGGCCAGGnTGCGGGCCCCAAGCAGCACGGCATCCTAGACTGTGTGAATGCCCACTGACCCTGCCCAG G A 398 GTGTGGGGGCACACAGCACCGACCAGTGAGACTCATACCGGCTTCCTGGGGCCAGGATGnGGGCCCCAAGCAGCACGGCATCCTAGACTGTGTGAATGCCCACTGACCCTGCCCAGCCC G C 399 CCAGCCCCACAGTTTCATTCTGAGAGAAGTGATTTCTTGCTTCTGCACTTACAGGCCCAnGACCTGACCTGCTTCTGAAGAGCAGGGGTTTTGGCAGGAGGGGGAGATGCTGAGAGCCG G A 400 ACCTGCTTCTGAAGAGCAGGGGTTTTGGCAGGAGGGGGAGATGCTGAGAGCCGATGGGGnTCCAGGTCTCCTCCCAGGTCCCACTCTCTGGGGCAGCGCTTGGAAAAGATTGTCCAGCC A G 401 AGCTGAAGGTTCCTGGAAGTTATGAATAGCTTTGCCATGAAGGGCATGGTTTGTGGTCAnGGTTCACAGGAACTTGGGAGACCCTGCAGCTCGGACGTCCTGAGGTTGGTGGCACCCTG C T 402 TGCCATGAAGGGCATGGTTTGTGGTCATGGTTCACAGGAACTTGGGAGACCCTGCAGCTnGGACGTCCTGAGGTTGGTGGCACCCTGATTTCCTAAGCTCGCTGGGGAACGGGGTGCTA T C 403 GGGCATGGTTTGTGGTCATGGTTCACAGGAACTTGGGAGACCCTGCAGCTCGGACGTCCnGAGGTTGGTGGCACCCTGATTTCCTAAGCTCGCTGGGGAACGGGGTGCTACTTCTCCCT C T 404 GGACGTCCTGAGGTTGGTGGCACCCTGATTTCCTAAGCTCGCTGGGGAACGGGGTGCTAnTTCTCCCTGGCTGACCTCCCTCTGCTCTGCATCACCCAGTTCTGAGAGCAGAGTGGTGC T C 405 TGCTACTTCTCCCTGGCTGACCTCCCTCTGCTCTGCATCACCCAGTTCTGAGAGCAGAGnGGTGCTGGGGGCACAGCCTCTCGCATCTGACACTTGTGTTCAAACCACCCATGCTGGTG C T 406 TTCTCCCTGGCTGACCTCCCTCTGCTCTGCATCACCCAGTTCTGAGAGCAGAGTGGTGCnGGGGCACAGCCTCTCGCATCTGACACTTGTGTTCAAACCACCCATGCTGGTGTTCGGGG TG T 407 AGTGGTGCTGGGGGCACAGCCTCTCGCATCTGACACTTGTGTTCAAACCACCCATGCTGnTGTTCGGGGGGCCACCTATGGGGAAGGCTCCTCACTGCAGGGGTGCCCCTGTCCCCTGA C G 408 GGTGTTCGGGGGGCCACCTATGGGGAAGGCTCCTCACTGCAGGGGTGCCCCTGTCCCCTnAGAGATCAGAAGTCCCAGTCTGGATGTCGAATGGCCGAGCTCCCTCCAGAGGCTCCAGG C G 409 GGGGAAGGCTCCTCACTGCAGGGGTGCCCCTGTCCCCTGAGAGATCAGAAGTCCCAGTCnGGATGTCGAATGGCCGAGCTCCCTCCAGAGGCTCCAGGGAGGGATCCTTGCCCCCTCCG C T 410 AAGGCTCCTCACTGCAGGGGTGCCCCTGTCCCCTGAGAGATCAGAAGTCCCAGTCTGGAnGTCGAATGGCCGAGCTCCCTCCAGAGGCTCCAGGGAGGGATCCTTGCCCCCTCCGCCGC C T 411 TCCAGAGGCTCCAGGGAGGGATCCTTGCCCCCTCCGCCGCCGCCTCCAGCTCCTGGTGCnGCACCCTTGGGCCCGATCTCGTAGACGCCTCAGTCCAGTCTCTGCCTCCGTGTTCACTG T C 412 AGCTCCTGGTGCCGCACCCTTGGGCCCGATCTCGTAGACGCCTCAGTCCAGTCTCTGCCnCCGTGTTCACTGGCATTCTCCCCATGTCCCCTCTGTGTCCCCGTTTTCTCTCACAAGGA C T 413 CCGCACCCTTGGGCCCGATCTCGTAGACGCCTCAGTCCAGTCTCTGCCTCCGTGTTCACnGGCATTCTCCCCATGTCCCCTCTGTGTCCCCGTTTTCTCTCACAAGGACACCGGACATA G T 414 GACCTAGATTCCAAACAAGATTCCATCCTGAAGTTCCTGGTGGACGTGAGTTCTGGAGCnACGCCCTTCAACCCCATCACAGCTTGCGGTTCATCGCAAAACACGGAACCTGGGATTTA A G 415 AGCTTGCGGTTCATCGCAAAACACGGAACCTGGGATTTATCGTAAAACCCAGGTTCTTCnTGAAACACTGAGCTTCGAGGCTTGTTGCAAGAATTAAAGGTGCTAATACAGATCAGGGC A G 416 AACAGTCTCTCCGGGAAGGAAACCAGAGGCCAGAGAGCAAGCCAGAGCTAGTCTAGGAGnTCCCTGAGCCTCCACCCAAGATGCCGACCAGGCCAGCGGGCCCCCTGGAAAGACCCTAC G A 417 TCCCTGAGCCTCCACCCAAGATGCCGACCAGGCCAGCGGGCCCCCTGGAAAGACCCTACnGTCTAGGGGGGGAACAGGAGCCGACCCGCCAGGCCCCCGCTATCAGGAGACACCCCAAC C A 418 AGGGGGGGAACAGGAGCCGACCCGCCAGGCCCCCGCTATCAGGAGACACCCCAACCTTGnTCCTGTTCCCCTACCCCAGTACGCCCACCCGACCCCTGAGATGAGTGGTTTACTTGCTT G C 419 CAGGCCCCCGCTATCAGGAGACACCCCAACCTTGCTCCTGTTCCCCTACCCCAGTACGCnCACCCGACCCCTGAGATGAGTGGTTTACTTGCTTAGAATGTCAATTGAAGGCTTTTGTA A C 420 CACCCCAACCTTGCTCCTGTTCCCCTACCCCAGTACGCCCACCCGACCCCTGAGATGAGnGGTTTACTTGCTTAGAATGTCAATTGAAGGCTTTTGTACCCCCTTTGCCAGTGGCACAG C T 421 ACCCCAACCTTGCTCCTGTTCCCCTACCCCAGTACGCCCACCCGACCCCTGAGATGAGTnGTTTACTTGCTTAGAATGTCAATTGAAGGCTTTTGTACCCCCTTTGCCAGTGGCACAGG A G 422 ACCTTGCTCCTGTTCCCCTACCCCAGTACGCCCACCCGACCCCTGAGATGAGTGGTTTAnTTGCTTAGAATGTCAATTGAAGGCTTTTGTACCCCCTTTGCCAGTGGCACAGGGCACCC G C 423 CCCTCCCTGCTCGGGCCCCCTCCATACTCAGCGACACACCCAGCACCAGCATTCCCACCnCTCCTGAGGTCTGAAGGCAGCTCGCTGTGGTCTGAGCGGTGCGGAGGGAAGTGCCCTGG G A 424 GAGGGAAGTGCCCTGGGAGATTTAAAATGTGAGAGGTGGGAGGTGGGAGGTTGGGTCCTnTAGGCCTTCCCATCCCACGTGCCTGCACGGAGCCCTAGTGCTACTCAGTCATGCCCCCG C G 425 GTGAGAGGTGGGAGGTGGGAGGTTGGGTCCTGTAGGCCTTCCCATCCCACGTGCCTGCAnGGAGCCCTAGTGCTACTCAGTCATGCCCCCGCAGCAGGGGTCAGGTCACTTTCCCATCC T C 426 AGGCCTTCCCATCCCACGTGCCTGCACGGAGCCCTAGTGCTACTCAGTCATGCCCCCGCnGCAGGGGTCAGGTCACTTTCCCATCCTGGGGGTTATTATGACTGTTGTCATTGTTGTTG C A 427 GGGCAGCGGGTGCTTGCAGAGCCCTCGATACTGACCAGGTTCCCCCCTCGGAGCTCGACnTGAACCCCATGTCACCCTCGCCCCAGCCTGCAGAGGGTGGGGTGACTGCAGAGATCCCT G C 428 ATACTGACCAGGTTCCCCCCTCGGAGCTCGACCTGAACCCCATGTCACCCTCGCCCCAGnCTGCAGAGGGTGGGGTGACTGCAGAGATCCCTTTACCCAAGGCCACAGTCACATGGTTT G C 429 AAGTGTTCCTGGCGCTGGCAGCCAGCCTGGACCCAGAGCCTGGACACCCCCTGCGCCCCnACTTCTGGGGCGTACCAGGAACCGTCCAGGCCCAGAGGGGGCCTTCCTGCTTGGCCTCG T C 430 CGCTGGCAGCCAGCCTGGACCCAGAGCCTGGACACCCCCTGCGCCCCCACTTCTGGGGCnTACCAGGAACCGTCCAGGCCCAGAGGGGGCCTTCCTGCTTGGCCTCGAATGGAAGAAGG C G 431 GAATGGAAGAAGGCCTCCTATTGTCCTCGTAGAGGAAGCAACCCCAGGGCCCAAGGATAnGCCAGGGGGGATTCGGGGAACCGCGTGGCTGGGGGCCCGGCCCGGGCTGGCTGGCTGGC C G 432 TATAAGGCCCCGAGCCCACTGTCTCAGCCCTCCACTCCCTGCAGAGCTCAGAAGCGTGAnCCCAGCTGCAGCCATGAAGTGCCTCCTGCTTGCCCTGGCCCTCACTTGTGGCGCCCAGG T C 433 AGGCCCCGAGCCCACTGTCTCAGCCCTCCACTCCCTGCAGAGCTCAGAAGCGTGACCCCnGCTGCAGCCATGAAGTGCCTCCTGCTTGCCCTGGCCCTCACTTGTGGCGCCCAGGCCCT G A 434 CTCAGAAGCGTGACCCCAGCTGCAGCCATGAAGTGCCTCCTGCTTGCCCTGGCCCTCACnTGTGGCGCCCAGGCCCTCATTGTCACCCAGACCATGAAGGGCCTGGATATCCAGAAGGT C T 435 GCAGCCATGAAGTGCCTCCTGCTTGCCCTGGCCCTCACTTGTGGCGCCCAGGCCCTCATnGTCACCCAGACCATGAAGGGCCTGGATATCCAGAAGGTTCGAGGGTGCCCGGGTGGGTG C T 436 CAGGCCCTCATTGTCACCCAGACCATGAAGGGCCTGGATATCCAGAAGGTTCGAGGGTGnCCGGGTGGGTGGTGAGTTGCAGGGCAGGCAGGGGAGCTGGGCCTCAGAGACCAAGGGAG G C 437 GGGCAGCTTCAACCAGGCGTTTAGTGTCTTGCATTCTGGAGGCTGGAAGCCTGCAATCCnGGCATCGGCCCAGCTGGCTTCTCCTGCGGCCACTCTCCGGGGAGCAGACAGCCATCTTC A G 438 CCTCTTCCTGTGAGGTCACCAGGCCTGCTGGATCCACGCCCGCCCACACAGCCTCACGTnACCTTTGTCATCTCTTTAAAGGCCGTGTCTCCAGTCCTGTGTTGAGGTTCTGGGGGTTA G A 439 AGAGTCACTCTGCCCCTCAAATTTTCCCCACCTCCAGCTATGTCTCCCCAAGATCCAAAnGTTGCCACGTGTGCGGGGGCTCATCTGGGTCCCTCTTTGGGCTCAGAGTGAGTCTGGGG C T 440 CAGGGCTGCCCAGGCCAGGGTGGGACAGAGAGCCCACTGTGGGGCTGGGGGCCCCTTCCnGCCCCTGGAGTGCAGCTCAAGGTCCCTCCCCAGGTGGCGGGGACTTGGTACTCCTTGGC G C 441 GAAGCCCACCCCTGAGGGCGACCTGGAGATCCTGCTGCAGAAATGGTGGGCGTCCCCCCnAAAAAAAGCATGGAACCCCCACTCCCCAGGGATATGGACCCCCCCGGGGTGGGGTGCAG C CA 442 GGGCTTGGAGTTTCCTGGTACCCCTGGAGGTCCACCCAAGGCTGCTTATCCAGGGCTTTnTCTTTCTTTTTTTCCCCCAACTTTTATTAATTTGATGCTTCAGAACATCATCAAACAAA T C 443 AGATGGGGACCTGAACCCCAGGACTGCCTTTTGGGGTGCCTGTGGTCAAGGCTCTCCCCnACCTTTTCTCCCTGGCTCCATCTGACTTCTCCTGGCCCATCCACCCGGTCACCTGTGGC G A 444 CTTCTCCTGGCCCATCCACCCGGTCACCTGTGGCCCCAGAGGTGACAGTGAGTGCAGCCnAGGCCGGTTGGCCAGCCGGCCCCCTATGCCCACGCCACCCGCCTCCAGCCCCTCCTGGG G A 445 CACCCGGTCACCTGTGGCCCCAGAGGTGACAGTGAGTGCAGCCAAGGCCGGTTGGCCAGnCGGCCCCCTATGCCCACGCCACCCGCCTCCAGCCCCTCCTGGGGCCGCCTTCTGCCCCT T C 446 TCCTGATGAAAATGGTCCATGCCCGTGGCTCAGAAAGCAGCTGTCTTTCAGGGAGAACGnTGAGTGTGCTCAGAAGAAGATCATTGCAGAAAAAACCAAGATCCCTGCGGTGTTCAAGA A G 447 GGGACGCCCACCACCCCCCAGGGACTGTGGGCAGGTGCAGGGGGCTGGCGTCAGGCCCCnAGATGCTAAGGGGCTGGTGGTGATGAAGACACTGCCGTGCCACCTGCTTCCCTGGCCTC A G 448 GGACGCCCACCACCCCCCAGGGACTGTGGGCAGGTGCAGGGGGCTGGCGTCAGGCCCCGnGATGCTAAGGGGCTGGTGGTGATGAAGACACTGCCGTGCCACCTGCTTCCCTGGCCTCC G A 449 GATGAAGACACTGCCGTGCCACCTGCTTCCCTGGCCTCCCTGCCACCTGCCCGGGGCCTnGGGGCCGGTGGCCGTGGGCAGGTCCCGGCTGGGCAGGTCTGACACCCCAGGGTGACACC C T 450 ATGAAGACACTGCCGTGCCACCTGCTTCCCTGGCCTCCCTGCCACCTGCCCGGGGCCTTnGGGCCGGTGGCCGTGGGCAGGTCCCGGCTGGGCAGGTCTGACACCCCAGGGTGACACCC A G 451 GCAGGTCTGACACCCCAGGGTGACACCCGAGCTCTCTTTGCTGAGGGTGGGGTGGTGCTnGGGGCCCTCAGGCTGAGCTCAGGAGGTCCCTGTGCCCACCCAGGGGTAACCGAGAGCCG T C 452 TGGGGTGGTGCTCGGGGCCCTCAGGCTGAGCTCAGGAGGTCCCTGTGCCCACCCAGGGGnAACCGAGAGCCGCTGCCCGCTCCAGGGGTCCAGGTGCCCCACGATCCCAGCCCACCCCA T TA 453 CACATCTGCCCTTGGCCTCTTCAGGACTCACTCTGACTGGAGGCCCTGCACTGACTGATnCCAGGGTGCCCAGCCCAGGGTCTCCTGTGCCATCCGGCTGCACGGGGTTTGGATGCTGG A G 454 GGGGTTTGGATGCTGGTCCTGCCCCCAAGCTGCCCAGACACTGCAGGGCAGCTGGGGCCnCCCGCAGGCCTCGGTCAGGGAGAGCCCCAGCTGCCCCCGCTCAGCGCTGCCCCCCAACA G A 455 CACTGCAGGGCAGCTGGGGCCACCCGCAGGCCTCGGTCAGGGAGAGCCCCAGCTGCCCCnGCTCAGCGCTGCCCCCCAACAATTCCCCAGTCCTCAGGACGCATCCCTCTTCCCTTGCT T C 456 GTGGAGGGTCCCTGGCGGATCCAGAGTTGGGCTTCCAGAGTGAGGGCTTCCTGGGCCCCnTGTGCCTGGCAGTGGCAGCAGGGAAGGGGCCACACCATTTTGGGGCTGGGGGATGCCAG G A 457 TCCCTGGCGGATCCAGAGTTGGGCTTCCAGAGTGAGGGCTTCCTGGGCCCCATGTGCCTnGCAGTGGCAGCAGGGAAGGGGCCACACCATTTTGGGGCTGGGGGATGCCAGAGGGCGCT A G 458 GAGGGCTTCCTGGGCCCCATGTGCCTGGCAGTGGCAGCAGGGAAGGGGCCACACCATTTnGGGGCTGGGGGATGCCAGAGGGCGCTCCCCACCCCGTCCTCACCAAGTGGTGACCCCGG C T 459 AGGGCTTCCTGGGCCCCATGTGCCTGGCAGTGGCAGCAGGGAAGGGGCCACACCATTTTnGGGCTGGGGGATGCCAGAGGGCGCTCCCCACCCCGTCCTCACCAAGTGGTGACCCCGGG A G 460 CTCCCCACCCCGTCCTCACCAAGTGGTGACCCCGGGGGAGCCCCGCTGGTTGTGGGGGGnGCTGGGGGCTGACCAGAAACCCCCCTCCTGCTGGAACTCACTTTCCTCCTGTCTTGATC C T 461 GGGGGCTGACCAGAAACCCCCCTCCTGCTGGAACTCACTTTCCTCCTGTCTTGATCTCTnCCAGCCTTGAACGAGAACAAAGTCCTTGTGCTGGACACCGACTACAAAAAGTACCTGCT A T 462 GAAACCCCCCTCCTGCTGGAACTCACTTTCCTCCTGTCTTGATCTCTACCAGCCTTGAAnGAGAACAAAGTCCTTGTGCTGGACACCGACTACAAAAAGTACCTGCTCTTCTGCATGGA C T 463 CTACAAAAAGTACCTGCTCTTCTGCATGGAGAACAGTGCTGAGCCCGAGCAAAGCCTGGnCTGCCAGTGCCTGGGTGGGTGCCAACCCTGGCTGCCCAGGGAGACCAGCTGTGTGGTCC T C 464 GGGTCCCCGAGTCCCGCCAGGAGAGGGTGGTCATATACCGGGAGCCGGTGTCCTGGGGGnCTGTGGGTGACTGGGGACGGGGGCCAGACACACAGGCTGGGAGACGGGGGGCTGCAGCG T C 465 TGCCACTGGGCATTTTCAGGGCCCATGTGCCAGGAGGGCGTGGGCATCGGCGAGTGGAGnCTCCTGGCCGTGTCAGCTGGCCCAGGGGGAGGAGGGGACCCAGACAGCCAGAGGTGGGG T G 466 CCCCCTCCCCACCCCCTCCCCAGCTCCCTCTGTCCTGGGGTGTCCAGTCCCATCCTGACnCTCCCCCGCCACGGCTCTCCCTCCCCCACAGAGCAGTGCCACATCTAGGTGAGCCCCTG A G 467 CCCTCCCCACCCCCTCCCCAGCTCCCTCTGTCCTGGGGTGTCCAGTCCCATCCTGACGCnCCCCCGCCACGGCTCTCCCTCCCCCACAGAGCAGTGCCACATCTAGGTGAGCCCCTGCC C T 468 CCAAGGAGGGGCCGTCCTGAATCCCCAGCCACGGACAGGCTGGCAAGGGTCTGGCAGGTnCCCCAGGAATCACAGGGGAGCCCCATGTCCATTTCAGAGCCCGGGAGCCTTGGCCCCTC G A 469 GCATCACCGACAAAATGGACATGGGTTTGGGTGGACTCCAGGAGTTGGTGATGGACAGAnAGGCCTGGCATGCTGCGGTCCATGGGGTCACAAAGAGTCGGACACGACTGAGCGACTGA G A 470 ACTCATATTTATATATATACGTGAATGCTCAGTCACACTCAGTCATATCTGACTCTGTGnCCCATGGACTGTAGCCCTCCAGGCTCCTTCTGTCCACAGAATTCTCCAGGCAAGAATAC G A 471 ATCCCCTAGCCTGGAAGGCAGATTCTTAACCACTGGACCACCAGGGAAGTCCCCTGCCTnCCTGCATCTTAACCTCAGTTCAGTCGCTCAGTTGTGTCCGACTCTTTGCGACCCGATGA A G 472 GACACAGCATTGCTGTCCGGCGAATGGAGCCACCATCTGGATCCTTCAAGTGACCCTGGnCGGGGCAGGGCTGGCACTGGCCGTCCGGCCTGCACTTCCGTCGGGCTCCGGACTCCAGG G A 473 ACAAGAAGTGTGGGAGAAATGACCAAGATATCTTGAGGGAAAAAAATAAGGTTATATATnTAACTCTGCACATTATCTTAAAATTAATTCTGAATGAAAAGAAATCTTGAAAGCTCTAT C A 474 TATACCTTAAAAACTAAAAAAATAAAATAAAATAGGCTTTGATGTCCCAAGCAATCAAAnAAAAAGATTCTATGTTTGCTTATCAAATTAGCAAAATTTTTTAAAAATTTAACTCAGCA G A 475 TTTTCGGAAGGGCATCACCAAACACTATCCACATGGGAGGCGCCAGGTCGACACTGCAGnATTCCCAGGGAGGAAGGCAGGAGGTCGGGCCTGTATTTCAGCTGCAATGGTTACAGAAG G A 476 TGTTTTGTAGAATAATATTAGAAACCAAGGTCTGGGGCTGGGAGTGCTCGCTGCTCCTGnGGGCTCCTCGTTTCTAGGTCCTCTCAGCTGGGCAAGCAGGGAAGGCATGTGTGTAGTTG C T 477 CTGATGCTGGAAAAGATTGATGGCAGGATGATAAGGGGGCAACCGAGGATAAGATGCTTnGATGGCATCACCAACTCAATGGACATGAATTTAAGCAGATTCCAGGAGTTGGTGAAGGA T G 478 AAGGGGGCAACCGAGGATAAGATGCTTGGATGGCATCACCAACTCAATGGACATGAATTnAAGCAGATTCCAGGAGTTGGTGAAGGACAGGGAAGCCTGGCGTGCTGCAGTCCATGGGC T TA 479 CCATGGGCTGAGAAACAACAAAGCACAGACTCCACTGGTTTCCAAGGTGACTTCTCTCAnCACCTTCCTCAGCCCTCAGGGAGCTTACTTCTGGCATGTTTGATACAGTTCGATGACTT G A 480 CTTTACTGTCTCTGCAGTTTTGCCTTTTCCAGAATTTCACGTGGCTGGAATCATACAGTnGGTAGTCTTTTCAGATTGGCTTCTGGCTTCTTTCCCTTACCAATGTGTACTGATACTTC G A 481 GTGTCCGACTCTGTGTGACCCCATAGACTATACAGTCCATGGAATTCTCCAGGCCAGAAnACTGGAGTGGATAGCCATTCCCTTCTCCAGGGGATCTTCCCAACCCAGGGATCGAACTC T C 482 TAGGCTATCCCAGGGACTTCCCTGGTGGCCCAGTGGCTAGGACTCTGCGGTTCCAGTTCnGGGGGCCTGGGTTTGACCCCAGGTCAGGGAACTAGATCCCACTTGCCAAAACTAAGGGT A AG 483 CAAAAATATACTTTCCAGTTTCATTGCTGATAGAACTGATCTCGGAAACAGAGGGTCTGnATCAAGGTCACCTAGTAGGTTACAGGACCAGATGTAGTTTCCATCTCTGTCTGCACCAT A C 484 ATACTTTCCAGTTTCATTGCTGATAGAACTGATCTCGGAAACAGAGGGTCTGAATCAAGnTCACCTAGTAGGTTACAGGACCAGATGTAGTTTCCATCTCTGTCTGCACCATTATCATT G A 485 TTTCATTGCTGATAGAACTGATCTCGGAAACAGAGGGTCTGAATCAAGGTCACCTAGTAnGTTACAGGACCAGATGTAGTTTCCATCTCTGTCTGCACCATTATCATTAGGTGATTCTG G A 486 TTGCTGATAGAACTGATCTCGGAAACAGAGGGTCTGAATCAAGGTCACCTAGTAGGTTAnAGGACCAGATGTAGTTTCCATCTCTGTCTGCACCATTATCATTAGGTGATTCTGTGTTG C T 487 CTGATAGAACTGATCTCGGAAACAGAGGGTCTGAATCAAGGTCACCTAGTAGGTTACAGnACCAGATGTAGTTTCCATCTCTGTCTGCACCATTATCATTAGGTGATTCTGTGTTGCAG G A 488 ATCTCGGAAACAGAGGGTCTGAATCAAGGTCACCTAGTAGGTTACAGGACCAGATGTAGnTTCCATCTCTGTCTGCACCATTATCATTAGGTGATTCTGTGTTGCAGAGCCAAGTAGCA T C 489 AGGGTCTGAATCAAGGTCACCTAGTAGGTTACAGGACCAGATGTAGTTTCCATCTCTGTnTGCACCATTATCATTAGGTGATTCTGTGTTGCAGAGCCAAGTAGCACTACTATGATTAC C T 490 GTCTGAATCAAGGTCACCTAGTAGGTTACAGGACCAGATGTAGTTTCCATCTCTGTCTGnACCATTATCATTAGGTGATTCTGTGTTGCAGAGCCAAGTAGCACTACTATGATTACATA C A 491 CTGAATCAAGGTCACCTAGTAGGTTACAGGACCAGATGTAGTTTCCATCTCTGTCTGCAnCATTATCATTAGGTGATTCTGTGTTGCAGAGCCAAGTAGCACTACTATGATTACATATC C T 492 AATCAAGGTCACCTAGTAGGTTACAGGACCAGATGTAGTTTCCATCTCTGTCTGCACCAnTATCATTAGGTGATTCTGTGTTGCAGAGCCAAGTAGCACTACTATGATTACATATCTTT T A 493 AAGGTCACCTAGTAGGTTACAGGACCAGATGTAGTTTCCATCTCTGTCTGCACCATTATnATTAGGTGATTCTGTGTTGCAGAGCCAAGTAGCACTACTATGATTACATATCTTTTCCT C A 494 GTAGGTTACAGGACCAGATGTAGTTTCCATCTCTGTCTGCACCATTATCATTAGGTGATnCTGTGTTGCAGAGCCAAGTAGCACTACTATGATTACATATCTTTTCCTGTAGCCTTTTG T A 495 GTACCATCTCCCTCTGGGACGGTCGGTGCTGCCACCATCCCCCAGGAGTGACAACTGAGnCCAGTCAAGGACACTCTCAGATACGCCTCCTCACAGTCAGGATACCCTATGCTACTCGC C T 496 CCTGAGATAGTTACTTAAATTCTCTATACCACATGTTTCCTCATTCTGAAAACAGAGATnATGATAGTACTTTTACAAATGCTATTGCTGTAGAGATTAAATGTATTAATCCAGGTAAA A C 497 CAGGCACAATAGCAAGGCCCCTCTTGTGTTATTTTATGTTATTTTCCCCTCAACCTCTTnTTGTACTGTTTTTTCTGGATATTATTTTATGTTATTTTCCCCTAAACCTCTTATTATTC A G 498 TTTCAGCCATTGGCCACTACACGTCTCCTTTTTCTACTAATATCTGATCTAAAGCAATTnCATTTTCTGAAAAATTCAATAGTTATAAGAGGATACCTTGAAACCATAATTACAGCTAC T C 499 CAATTAAAATAAATAAATTAAAAATATATATAAAATATAAATAAAAATTTTTCAGGATTnAAAAAAAAGGTCACAACACTGGAATTTCAAGTTACCAAAATCTGCTGCTAAGCTAAGTC A T 500 CTCCTGCCTGTGCCTCCATGTGGGGCCCCTTTCATTTATTTTCCACCTATCCTCAGAGCnTTGTTCAAATTCCGCCTCCTCCAGGAAGCCTTCCGGGTCAATCCAGCTGGAAATGCGCT C T 501 CCCAAGCTTATTCTTCTATCCATGAGACTCTCCTGCAAGCACCCTCCTCTGTAGGCTTCnGCTTCCCCACCTGCAGTAATCAGAGGGGCCATCAGTGAGGGCCTCCTGAGGGCCAGGCA G A 502 ACAATTATAAACAATGCATGGTGCTTGTGGAAACCCAGACTCAAGGCATTTATGAAAACnAAACTCCCCCGTGGAGGGCAGGAAGGGCAGTGGGATAGAGGAGTAGAGGAATGCAATGG C G 503 CCTGCCACGCAGAAGAGGCAGGTTCAATCCCTGGGTCAGGAAGAGAAGGAAATGGCAGCnCACTCCAGTATCCCATGACAGAGGAACCTGGTAGGTATAGTCTATGGGGTTGCAAAAGA G A 504 ATAGGTATGATGCAGTTCATAATAAAATGTCTAAAAAGAGACCAAAATAAATAAAGAAGnGATGAGAGGACTTTCTGGTAGTCCAACGATTAAGAATCCACCCACCAGTGCAGGGAATG T C 505 AATGAGTAGTTTCTAGTGACATGAAAAAACGCTGATAGTGACATGAAAAAATACAGATAnAAAAAAAAAGATAATAGTGAAAAAAAGCTGGATGCAGAACACATTAACAGCATGGTCTG G GA 506 AAACTCCCAGCCATACCAGGTATTTCTCTGGTGTATAGATAGGCTTTCTAAAGCACCATnAGCATTTCAGACTCCTGTTTACCCAACAAGGATCATATACCTTTAAATTGCTTCCCCTC G A 507 TCCCATTCTGTTGTTTTCCTCTATTTCTTTGCATTGCTGAGGAAGGCTTTCTTATCTCTnCTTGCTATTCTTTGGAACTCTGCATTCAAATGAGTATATCTTTCCTTTACTCCTTTGCT C T 508 TTTCATGCACTGGAGGAGGAAATGGCAACCCACTCCAGTGTTCTTGCCTGGAGAATCCCnTGGACAGAGGAGCCTGGTGGGCTGCCGTCTATGGGGTCGCACAGAGTCGGACACGACTG G A 509 TTCATGCACTGGAGGAGGAAATGGCAACCCACTCCAGTGTTCTTGCCTGGAGAATCCCGnGGACAGAGGAGCCTGGTGGGCTGCCGTCTATGGGGTCGCACAGAGTCGGACACGACTGA T G 510 ACATTAGTTTTAGGCTTCTTTGTAATTTTTTCTTGTTTGTTGATGGTTTGACAAAAGGCnAAGTTTTTAAATACTCGGTTTTGAAAGGTGTTTTTTTATTTTTTATTTAAGTGTATTTG G A 511 TCTTTTTGTTTGGAGCAACCTCATGAAGTTGTTTTGTTTTTTGTTTTTTAACAGTCAAAnTGTATGGCTCATTGTAGAAAATACAGAAACATATAAAGAATTTACTAGTTCATCATCCC C T 512 ATCACACATATATTCCTGATAGGAATGTAAGATAGGACAATCACTCTGGAAAATACTTCnTCAGTCTCCTCTAAAACTAAATATATATGTACCGTGTGTATGTGCTCAGACCCTGAGTC G A 513 GTCACACAGGGATTGGTGAACTACAGACCCTCAGATATGGCAGGGAGCCACGAGCTCGTnGTCTTTGACTCCCATCCCCAACTCTATACCTGAATCCTGCCCCATCCCTCAGCCCTCTC C T 514 TGTCTCTGCTTTTGAATATGCTATCTAGCTTGGTCATAACCTTCCTTCCAAGGAGTAAGnGTATTTTCATTTCATGGCTGCAGTCACCATCTGCAGTGATTTTGGAGCCCAAAAAAATA C T 515 GAGTAAGCGTATTTTCATTTCATGGCTGCAGTCACCATCTGCAGTGATTTTGGAGCCCAnAAAAATAAAGTCTGACACTGTTTCCACTATTTCCCCATCTATTTCCCATGAAGTGATGG A G 516 GGTTCACATATTGCTGAAGCCTGGCTTGGAGAATTTTGAGCATTACTTTACTAGCGTGTnAGATGAGTGCAATTGTGCAGTAGTTTGAGCATTCTTTGGCATTGCCTTTCTTTGGGATT GAGATG GAGATG AGTGCA AGTGCA ATTGTG ATTGTG CA CG 517 GGCCAGGGGTCCCCAAATGGAGGAGACAGACTACAAGTGTCAGACATTTTAAACTATCTnTTAAGTGGCAGGAGGAAACAAACAAGTGTTAGATTTCTTCCCCTCCTCTATACAAATTT T C 518 GCCTGGAGAATCCCAGGGACCGGGGAGCCTGGTGGGCTGCCATCTATGGGGTCGCACAGnGTCGGACACGACTGAATCGACTTAGCAGCAGCAGCAGTAGCTACATAACATCCAACTAA C A 519 TCTCCTCCGGAGGCCAAGAATCCTGGCGTCTTTCATGGCTCAGCAACAACCTTTCAATAnAAGTACTATTATCAGCCCCATTTTATAAATATTGAGGCTTAGAGAGCCTAAATGAGTTG T G 520 ACCCAAATGAAGGGATACAGGGGCTGGCATGGGAAATAGTCAAGACAATAGGGCCAGGCnGCAAAGCACGGAGTGCCTAGAAAAAGCGTAGTTAGACCCCCGGCTCAGAAGGCGCACAG T G 521 CCCCGGCTCAGAAGGCGCACAGAACCCAAAATCCAGCGCCCACTGCGCCGACAGTGGACnCCAAGACCTAGAGACACACTAGGGCTGCTCAAGGGCGCACAGCGCAGCGGCGCCGGTCC G A 522 CGCCCACTGCGCCGACAGTGGACGCCAAGACCTAGAGACACACTAGGGCTGCTCAAGGGnGCACAGCGCAGCGGCGCCGGTCCCAGAGGCAGCTTCTCCAACCCCACCAGATCGATCCT C A 523 CACTGCCCCGTTCCGGAAGCCCTTAAGCATGGCCAGTGCTGCGTGGTAGCGGCGCTTGCnCAATAGTGCGTTGATCGCAAAGAGCAGAGCCCGCAGCTGCGGTGGGGCGACCATAATGC T G 524 AGGATGTGTCTGCTGTCACTCATACGAGCAGGGCCGATCACAGAGCTCACTCAACTCACnAGGGGAATGGGACGCAAGCACTCTCCCGAAGAGCGGTCTGATTGGAAGAGAGGGAAAGC G C 525 AGGAGTACATCAAAGCTGTATACTGTCACCCTGCTGATTTAACTTATATGCAGAGTACAnCATGAGAAACGCTGGGCTGGAAGAAGCACAAGCTGGAATCAAGATTGCCAGAAGAAATA T C 526 GTCTTTTCTGGCAATTTGATCTCTGGTTCCTCTGCCTTTTCTAAAACCAGCTTGAACATnGGGAAGTTCACGGTTCATGTACTGTTGAAGCCAAGATTGGAGAATTTTGAGCATTACTT C T 527 TTTTCTAATGAGTCAGCTCTTCGCACCAAGTGGCCATAGTATTGGAACTTCAGCTTCAGnATCAGTCCTTCCAATGAATATTCAGGGTTGATTTCCTTTAAGATGGACTCATTTGATCT C T 528 TGGATGGGGAAGCTGATGTGTTCAGCTGGGACCCACAGCCTGACTTTGGGGTTTCATAGnCATAGTCCAGTTCTTTTGACTCGTACTTTTATTCTTTTTTTTAAAAATTACTATATTTT C T 529 AATAGATGCCACCTCTCAATGGGAAAAACTGCAGGTCACACTGGAAAGGGCCTGGGTACnAGAAGAAGTAAAGAGTCGAGGCCATTCAGTCAGTGTACAGGATACCTTGCTTCATTGCA C T 530 AAGGCCTGACCTCGGGGTTAGTGATGCTCTATGAACGTGCCTCTGCAAGTTCTCTGCTCnCTCAGTACTAACCATGACACCCCTTGTCCCAAGAACATGCAAGGAGCCCCTCTGGGCCT G A 531 AGCTCAAGTCCCACATGACCCAGCACAAGAATGAGCAGGTAGGTGAGGGGGCGGGAGCCnGGGTGGGGCACAACCACCCAAGTCATGAGCCTTGGCTGATGCTGGGGTCTTGAACACGG G A 532 GGACTGCAGGTGAGGAGGCTGGGGCAATATTGGGGTTCTCGTAGCTAAATCTGTCCTAGnTTGGCATATGGGAGACGGGCCCAGAGAGGGGAAGGCCCACGGTCAAGGGTCACTCAAAG G A 533 TTTTCATGTTCCTGGCCCACTTTACTCATTCATCTTATTTATAGACTCTGGGTATATGAnTTTGACCCTGGTGGCTCAGATGTAAAGAATCTGCCTGCAATGCAGGAGACCTAGGTTTG C T 534 ACTTCCCTGGTGGTCCTGTGGTTAAAACGCCACGCTTCCACTGCAGTGAGCATAGTCTGnATCCCTGGTTGAGAACTAAGATCCCACATGCCGATGATGTGGCCAAAAGAAGGGGATGG G A 535 TGCAGCTGAAGAAGCTGATGGTCAGGGACAGGAGGATACTTTTACCAGCAAGCAGAGGTnGAATGTGAAATCAGGTCACCTGATCCCAAACTTAGAGCTTTTTTTTACTAGACCATATC G T 536 CTTTTATCAGCTACTTGTACGTGTGTGTGTCATCTGCACTGAACTGTGTGCCCTTGTAGnGTCTCATCCATCTTTCTACCTCTTAGTGTGCCTGAGACTATAGCCGGGAAACCAAGGAA C T 537 AAAGGAGATCAGTCCTGGGTGTTCATTGGAGGGACTGATGTTGAAGCTGAAATCCCAATnCTTTGGCCACCTGATGCGGAGAGCTGATTCATTTGAAAAGACCCTGATGCTGGGAAAGA A T 538 TCTGAGCGCCTACTGCACACTGCCAGGAAAGATGGGCTTGTGTCAGTGCGGGGAGCCTGnCTTCTCCCTGTCCCTGGCCATGCAGACCCTCCTTGCTACCTCTCAGCTCTCAGAACAGC C G 539 GAGCCGTATTCATCGTGTCCCTGAGGCCTGGGCTTCAGATGAACAGACCCTCTGCACAAnGGGAAGTTGAGGCAGGACAGAGTCATGCCACTTACCCTAAAAAATACCTGCTACTGAAA G T 540 AGAGTCCACATGCCAAGGGACAACCATCACATGCCAAGTATCACAACCATTGAACCCTGnGGGCTCTAGAGCCTGTGCTCTGCAACAAGAGAAGACACTGCAAGGAGAAGCATGTGCCC T C 541 CCATGTCTTGACTGTTTGCAGCCCTGTGGACTGTAGCATGCCAGGCTCCTCTGTCCACTnTCTCCCAAAGTTTGCTCAGATTCATGTCCATTGAGTCAATGATGCTATCTAACCATCTC G A 542 TGCAGTTTGCTAACACCTAAGCTACAGTGTGAAGAAAGAGCTTAAGTCATGGAGTTATTnGAACCAGTTGTAGGTCGTACACTGTAATTTTAACAATGCTACTGCAAGAGCTATCTGGT G A 543 ACCAAAACATAAAACAGAAGCAATATTATTACAAATAAAGGCTTTAAAAATGGTTCACAnAAAAAAAAAATCTTAAGAAAATAAAGGGAATATATTGGCTTGAGTGTGTGCTGAGTCAC T TA 544 CCACCATTCTCAGTATGGGTTTCATCATTAATTATTAAGGTCATCTCACAGTCCAAGAGnACTGCCTGAATTCCAGTCAGAAAATGGATTTTCTCTCTTTCTAGGCAGAAGGAAAAAAA G A 545 ACTAGTGATTTGTATGGTTTCCTTATTCTTTTAAGTTTTCTATCCACTTTATCTTACCTnGTTAGCTTTTGATGGAGTTTTGTTTTTGTTTTGAAATGTTTTTAAGCTTTTATTTAGAA C T 546 CCAGGTTTTCCACATCAGTGCCAACCGTTGTTACTCTGTGTGTATGTGTGGTGGTGGTGnTCAGTTGCTAAGTCGTGTCCAACTCTGCGACCCCATAGACTGCAGCATGACAGGCTTCC T G 547 TTGCTATTGAAGAAACAGAAGGCTTTGGACAAGAGTGAATTCTGAGAGCCTGCACCACCnAAGGACAAGAATTTATTTGCAACGTTTGTCCTTTTCCTTCTTTGCCTATTGCACACTTG A G 548 AAGGTGATAACTGCTCTGGGGAAAATTAAGCAAGTACTAGGAGGGAGGATAGTCACTGGnGTGGGAACTGCAATATTCAGTAAGATCATTCAGGAAGGCTTCCCTTGAGGAGACCTTGG G T 549 TCCTGGGGGATTCCCAGAATTGTGATAGAAGGCCGCCAGTGCAGTTGAGGCCAAGAGGGnAAGAGTGAGGTAGATAAACCTAGAGAAGCAACAGGGAGGAAGATCCTACAGGCCTCACG C T 550 AGAGTCTATTTTGGGGAAGATGATGGGTTCATCTTGAGTAGGTCAAGTCTGAGATGTCTnCTAGACTTCCATCTAGAGACATAACACATGCCAGGCCTTTGGATTCAGGGAAGATGCAG G T 551 GGGAGACGGCGCCCCTCCGCGCCCGCCCCTGCGCAGGCTGTGACGTCACAGGACTGTGAnGCGCCCTGGGAGCCCCCGCCCCTTCGCGGCGCGGGGCCGGGAACACAGGCTCTCTGCGC C T 552 AGGTGGGGTATGGGACCGGGAGCTGGGTCCCTGTTCTGGGGAGGTTGGGAAAGGTCAAGnTCAAGGCTGGGGTCAGTGTCCAGTCAGAGGTAACTGCCTCTAGAAGGGCCTGGGATGGG G T 553 CCATTCTGTCACCGCAGGAACTCATCTAGAAGGCTGATGGAACCCATCTTACAGACGAGnAAACTGAGGCACCAAGAGTTAGTTGGCCTAAGGCTGTACTGGGAGAGCTGGACTGGTGG G C 554 CATGGCCAACAGCCCTGGGCTGCAGTGTCCTGGAGAGGCAGGGAACCCCAGGCATGTCCnGGTTCCCCAGGTCTCATTGTGTTGGGGATGCTGACACCTGACAGCCACGACTGGGAGAA C T 555 GTGCTATGAAGGGAACACACAGAATGCCAAGACAGAGACCGTGGGGCAGGGAAACCTCAnAGATCTCTCTGGGGAGGTGACCATTAACTGCTATGAACTTCTAAATGTCCATTTGCACT CAGA C 556 CTGAGTCTGCTGCACCAGCCAGAAGAGAATAAATGTGTCTGCAGTTCCTATGGCTCCTCnCGTCTTCTTCCACCCTCTTAGCTTGCGCCTTGCCTATCCTGGGTTCAACTAATAGTTCG G A 557 TAATATGCAATTTATATATTCTATATATAATACAGAATACATATCTTATATATTCTATAnTATATATATATTCTATATTATATTATATAACCTAAACCATCCCTCCCCACTCCATCTAT TTA T 558 CTGCCAGAGCAACTCCGTCTTAGGGGAAAGAGGACCAACGTCCCCAGACTCATCCCATCnCAAACTAGGGTATGTTCACACGTTCTGTGCCTTTGGGACTTGCCAAGGGGCCCCAGGCT A AC 559 TCCGCAGCAAGAGACCACCGCAATGACAAGCTAGCGCATCCTAACTGGAGTGTAGCCCCnACTCGCCACAAATAAAGAAAAGCCTGTATAGCAACAGAGACCCAGCAGAGGCAAAAGTA C G 560 GGAGGTCAGGTATCTTCACACCTTCTGTTCCCACAGCTCTGTGGCCCTTGGTGGGGGTTnGGGGGGGGGTGTCACAAGATGGCGGTGGCCCCCAGGAGCTATCTGTGGCCTTTCACACG G GA 561 GAGGACAGGTGTGCTGGGTTCCCTGCTTCTTTTAGCCCAGACCCAGGCCTGACCAGAACnCGGGTAGGACATATGGACCACAGACAGCTGGAGAGCCTGGCTGAGGAAGGCTGCCAGAA G A 562 ACATTAAAAACATACATATGGGGTTGAAACGGATGTCAATTCAGTTCAGTCGCTCAGTCnTATCCAACTCTTCGCGACCCCATGAATCGCAGCACGCCAGGCCTCCCTCCCTGTCCATC G A 563 ACGTACTCCTTTTCCTATTTGGAACCAGTCTGTTGTTCCATGTCCAGTTCTAACTGTTGnTTCCTGACCTGCATACAGATTTCTCAAGAGGCAGCTCAGGTGGAGTGGTATTCCCATCT C G 564 GAAGCCATAGACTGCAGGAATGAAATCCCAGGAACTAAGAAGGAAGAAGGAGAGGCAAAnGACTACCACTAGACTTCCCATATACATCATGGCGTACTCCCAAAAGAAGATCCAAAAGG C T 565 AATATATAGAACAAACATGGACAGAGTTACAGAGGAAAAATACACAAATCCACCATCAGnGGATAACTGGTAGATCTAATAGACAAAAATCATAATGAAATAGAAATATGAATAGCATA C T 566 TCCAGATTTCTGGTGAGCAGTGTGGTCTTGCATAAAAAAACTATAAAATTTCTCACACTnTTGGTGCTAAAAATTTAGCTGGAAGAACACACCTTAAGGAAATTAAATGTCTATACTAC T G 567 CATGCCCCAACTAGAAGTTCCCATGCTGCAAGTAAAGATCCCACATGTAGCTATGAAGAnAGAAGATCCTGTGCACCACAACTAAGTCCTGGCTCAGCCAAATAATTAATTAATTAATT T C 568 AGCTACAATTAGCCACCAGGTCTGTCTCACTAAAAAAAATGCACAACCTAAAAAGTTGAnATTTATATTTTATTTGGTGGACAAGACTGAGGACTTAAGCTTGAGACAAACCATCTCAG G C 569 TGGAGGCTGGAACCCAGATCAGCATCGAGTGAAAAAGCATCTGTGAAGGGTTGATTGTGnGTGTGCCTGTGTGAGGCTTTGTCCCAAAAGAGACAGAATGGCTCTGTCTCTTTTCCTGG C T 570 TGGTCCAGTGGCTAAGATTCTGAGCTCCCAATGCAGAGGGCCCAAGTTCGATCCCTGGTnAGGGAACTAGATCCCACATACTGCAACGAAGACCTGGTGCAGGCAATTAAGTAAATAAA C T 571 CTTTGGGAGCTTCTCCTTTGTTATGATATGAATGATCAAGTGGTGTGTCTAAGCAACACnTGTGGCTGGGAAGCATGGTTAGCAGTGGGGGAATAATCAACCTTAGGCTCCACCCTCCA T A 572 ACTAGAAGAACTAAAATATACACCATAAATACTGCTGAATTGTAGGAATACTGGCTAACnGATAACATTCTTCTTCATAATTCTCTGATCTGAATTTCAATTTATCTTTAGTAAACTCT G A 573 CAAAAAACCAGTCAAAAGGATGCCTCTTCTGAGAAGTCTTCCATGACCTCAGTCCCCAAnAGGAGTTGCCCCTTCTGCCTTTTGGGTTCAGAGTCTGTGTCTGGCATTCTAGAGCACCC G A 574 TAATGGAGGTGCCTCTTTCTCCTGCTAAAACAAAAGCCTCAGCAATACTGTCCTGGTGTnTATAGGGTCAATGGTCAGGCGACTCAGGGAACAAACACCTATAAGGTATCTTTGGTCTG T C 575 CTACAGTTGTATTTCATCTTGTTAGGTTATGTGGGACAGCACAGTATAAAAGACAAAGCnTGAGTTTTGTGGTCAGAGCCCATCTGCCTTTCTCTCACTTGAGGATCAAACAGCTACAC G C 576 TTAAAATAATCACAACTTCTACCTTACATTTTAAAAAGTTTTTTATTCATTTATTTATTnGACTGCTCTGTTCTGGTGTGGCTTGTGGCATTTTAGTTCCCTGACCGGGGAATGAACTG C T 577 ATTTTATGAGGACCTAATATAACAAAGACTAATTTGAGCAAAATACACACACAAATACAnATACACGTGCACATACACACACTTTCAGAGGTTATATTTGAAACTTTTTACTTACTAAC TATAC T 578 TATCTTTAGGGTAGCTATCAAATTCAACCAGGGAATCCAGACTTCTTTTTTTGTGAATAnTGCAACGGTGGCTCCAACAATCCATAACACCTTGCAAGAAATTGTAGACTGGCTAATGA C T 579 CCCACCAGCCATCAGTTTTCAATTTCTAATTAAGTCTAGTCAGTTTCTAATTAAGTCTAnTAAGTCTAAGTCTAACCTGGATTGAGTTAAATCCAAGTATAACTTACAAAACTGGTAGA A G 580 CTGCCTGCAATGCAGGAGACCCAGGTTCAATCCCTGGGTGGGGAAGATCCCTTGGCGAAnGGAACGGCTACCCGCTCCAGTATTCTTGCCTGGAGAATCCCACGAACAGAGGAGCCTGG C T 581 AATCGGAAGAGAAGCACTTCCTGGCTTCGGACCCAAATCACAGAGGTTTCCTCTCCCCTnTCCATCAACCTCATGCCTTTCCCTCCACCCCCAGGCCCCACTGACCTAGATCATGGGTC C T 582 AGAGTTAGGATTCCAAGCCTAGACTGTCTCCAAAGCATATACTTTGTTCTACTTCTTGGnAATGGCATTCAGGCTATTTCTCCTAAGGTTTGGCAAAGACGTAACTGTCTTCCTGTGAG G A 583 TAGCTGGCATCTATTGATCTCTCAGTGCCAGCCAGACACTGGGGAAGGGCTCAGTAATCnCTCAAGGAGGAAGTTACAACCATCCCTGAAGTATGAAGAAATTGAGGCTCGGGATGAAC C T 584 TGGGTTTCCTGCATTGCAAGTGGATGCTTTTACCAACTGAGCCACCAGGGAAGTGACTCnATTCAGTAGGTTGTCACTTTGTTTTATCAATGGTTTCCTTTGCAATGCGAAAGCTTGTA C T 585 CTCGTCCCTGTACCTGTTGAAGAAACTGGGTCATTTGTCCTGAGTATAGGCATTAGACTnAACTAGATTCGGGTTCACTTTTTTTTATATATAATTGTTTCTTTTTTATTGGAGTATAG C G 586 GCATCTCTGGCTCCCAGCCTAGAGGCAAATAGACAAGTAAGGTGGCAACAAAGGCAGTAnGGGAAGGCACTTGGGAGAGAGCATCTGAGCAGAGGGCCCTGTGAGAGGGGGTTGTCAGG A G 587 CTAGGTCTCAGCTTCCATATTTATATTATAGGAAAGATGATACCTACGGTCCTAGAATTnTATACCTACCAGAATCTATCCTGTAGGGTATTGTGAGTGAGGATGAATGATGAGAAGTA G A 588 TTTAGGGCTGGCATGCTGAGGACTAAATCCTCACAAGGCCTGAGTGCCACACAGAGTGTnTTCTATCCAGTCACATCCTTCTGTCTGCTTCCCTTTATTGCTCCTGAGTACCTTCCGTG G A 589 GAGATGGCTGTCTGTGGAAGTTAGTCATTTACTCTCTTGACAAGGCATTCAAACACATCnGCAAGCCCGTAATCACCCTGAAAAGAAGCTGATGGGGTACAGTAAGGTCCTGGGAAGAT C T 590 TGTATACTGTCACCCTGCTTATTTAACTTCTATGCTGGGCTGGATGAATCACCAGCTGGnATTAAGATTAAGATATCAACAACCTCATATATGCAGATGATACCACCGTAATGGTAGAA A G 591 ATGAGGAAACTAAGACCCAGGGAGAGGCTGCAACTTAAGGTAGTTTTAGGACAAAAAAAnTTTTTTTAAAGTTTCCATTTACAAGATGAGGAGAAAATTTACCCAAGGAGCATGAACAT A T 592 GGCAGAATATTGAAAGCATGCTCCAAAATGCACACAGAGCCCCTCAACAAATACTGAGAnACTTACTGGTTCCACATTTAAGGAAATCTCCATCCAATCATTACTTGACCACTAAGCTA G T 593 TTGAAACAGAGTGCAGAGGTACTGATAGGAGATGAGGTCAGATCATGCCAGCACCACAAnAAGTATGGCCTCACGAGCCAGAGAAAAGAGGGTGGATTTTATTTTTAGTGCAGTGGGGA T G 594 CACCCACTGCCATCCATGGGCTCAGGCCGCTGAGCTGGGGTTCCCAGTTCCTCCTCCTCnTCCACTGGCCCGACTCCCATGTCTGACTCCAGCAGGAGCTGTTTCTCCCCTTCTGTGTC C G 595 GTAGGGATAGGTTGCTGGGTGGAGGGAAGACTTTTCCAGAAATCAGCTTGCCAATTTTCnCCTTCCCTCCTCTCTTCTGTCACTCGTGGGAGACGACCAGGGGCACAGAACACGGCAGC C T 596 GACACAGTCAGTGTGAAGTGGGTTCCAAGCAGTGGGCCATAGGAGAGGGCTGAGGGGTCnCAGGCCTTACCTGAGCCCTGGGAGGGAGGCTGGCAGGCCGGCAGACCGGTCATATGGGG T C 597 GTGGCTGAGGGACATGCTAGCCAGCTCGGCTCAAAAGTCCTGCAGCTGAGGGATGTCCCnGTACAAATCCAGGGTCTCGGGATTCGAGAAGGCCCCTCGGTGCTCCACCGTCTTCCCAG G A 598 ACAGGTGTGATGTGGGGCTGGGGGCAGAACTGAACTAACAGTTCTCACCCCCAAAGGCAnGCCTCCTAGTGGGGTCCACCCTACACCCAGTTCTGAGATGCAGCGGTGCGTGAGAAACA T C 599 GAGGAGGCAGGGATCAGAGCTTTAAATAAAGAGACTTCCCAGCTCAGGGGCAGGGTGCCnCTCCAAAGATGAGCGAAGAGGGCAGCCTGAGTGAGTGACGGGCCTGAAATTAATTATCC A G 600 GGTTAACACTCCACAGCTTCCAGTACAGGGGGCATGGGTTCGATCCCTGGTAGGGGAACnAAGATCCTACATGCCATGTGGTGTGGCCAAAAAAATAAAACCTCCAGGTCTCACCTCTC T C 601 CATGTTGCCATGAAGAATGTGTTCCTTCAGGTGCTGGATGAGCGTCCCCTGGGGAGAAGnGAGTGAGCCAAGCAGCTTCCTCCGGGGCACAAAGGCACGCGTGGAATAGACACTGGGCC T C 602 ATCCAACCATCTCATCCCCTTCTCCTGCCTTCAATCTTTCCCAGCATGAGGGTGTTTTCnAATGAGTCAGCTCCTTGCCTTAGGTGACCAAAGTATGAATCTTAAGGAGTCAAATGAAT T C 603 TTTAGAGATCTCTTCTGACTCGTGAAGGTCACAGCAAGAAAGTGGGATCAAGGTCCCACnAGAGTTTCTATGACAGAAATCCTGCCAGACAATGATCCTGTTCTCACTGATTGCCTATA A G 604 GAAGAAAGTACTATTATTCCCATTTTACAGATGGGGAAACCCAGGCACAGCAAGGTTGAnCGCTAGCCCAGGGCCGCACAGCTGACATACGACCCAGAGCAGTCTGGCTGGAAGCCACA T A 605 CTCCTGCTAATGCAGGGGTCACGGGTTCAATCCCTGGTCCAGGAAGATCCATCATGCTGnGGAGCAACTTAGCTCATGCACCTCAGCTATCGAGCCCACACACCCTAGAGCCCTTACTC A C 606 CTAGGACCAGGGAGGAGGCCAAGAGCCCAGGCCATGGGGCATCTATGACAGCACAGATCnGGGCAAAGTAGGAAGAGTCAGCACAGCTGTGATGAGGGGAAGGGGAGGCCTTAGGGCTC C T 607 GAAGCCAATGACCACATTGGGAGGAACTCAAGCAGTCCTAGGTGGCAAGTAGCGGAGGCnCCCTGCCCACAACCAGCAATGACTCACTGCCATGCGAGCCAGCCCCTGAATAGTGTGGC C A 608 GCAGAGCGCTCAGCCTGATGGCCTTCACGCCCAGCCAATGATGTCAGTCCTCTCATTATnTCCATTTTACAGATGAGGGAAACCAAGGCTCGGGAGATCCAGTGACTTCCCTCTGACCA G A 609 AGGACCGGGAGCAGGCCGGGGACCGAGCCGGGGGCGGCAGCAGAGGCCGGGAGCGGGACnCCGGGCGAGCGGCGAGGCAGACGTGGAGCAACTGCACGCGGAGCAGCCGCCCCGCCCGA T C 610 GTGTAGGCTTTGCAGATACATCACCGAGCAAAGCGTTAATTCCTGCCCTCAGTCAACAGnAGATAAGGGGTAGGGGACAGGTGTGGGGAGGAGCGGGGTCAATCAACAAATACATTATA A G 611 TTATGGGTGGAGAAGGCAATGGCAACCCACTCCAGTATTCTTGCCTGGAGAATCCCAGGnATGGAGGAGCCTGGTGGGCTGCCGTCTATGGGGTCACACAGAGTTGGACACAACTGACG G A 612 TACACCTGACAGCTACTTGGTTCATTCTTATTTCTTTCAGCTCAGAGCCCCCCACCCCCnCCCCCATAGAGGCACAGGACCTGTAGGGGAAGCCAAGGGAGAAGTAAGCTACAGTCAAA A C 613 ACCAAGAATCTTAAACTTTCTGTGGGTAACCCCTCTTAGGTCTCTGAAATTCCCATCTTnCCCATCTTACCAGTTGCTTTCTTTTTTCTTTTTTGGCTGCACTGGCTCATGGTTGCTAA T C 614 GGCCTGAGGCATGCTTGGCACAGTCAAAAGGTAGTGACCATACGTATAGGGCCTTGGGAnGCTCTAGGGTAAGGACTTCAGATTTCATTCAAAGTGCAATCAGAAGCCACTTGGAAAGT G A 615 CAAAAGCTTTTCAGACAAGCAAAAGCTGAGAGAATTCTGCACCACCTACATGTCTATATnCTTAAAGAGATGTGAATACCAGACCACCTGACCTGCCAGTTGAGAAATCTGTATCCTGG C T 616 CCATGTGCCACAACTAAAGATCCTGCATGCTGCAACTAAGGCCCAGTGCAGCCAAATAAnTAAGTATTTTTTAGGAAAGGAAGATGAAGCCATAAAATCTGTTTGTTTGATTTTTTAAG C A 617 GCAAGCTCCGGGAGTTGGTGAAGGACAGGGAGGCCTGGCATGCAGCAGTCCATGGGGTCnCAAAGAGTCGGACACGACTGAGCAACTAAACTGAGCTGACTCGAAGAAAGGCAAATACA A G 618 CACTCATCTCACATGCTAGTAAAGTAATGCTTAAAATTCTCCAAGCCAGGCAAAACATGnACCATGAACTTCCAGATGTTTAAGCTGGTTTTAGAAAAGGCAGAGGAACCAGAGATCAA G A 619 GTTAGAGGAAACTTTTGGGATTAAAGATTTTGATTCGATATGTACTTATAAGAGAGTATnTTAAGTTGCATGATAAAAATGCAACTTTAAACAGAAAACCTTGTGAATCTGTGACTGTA G A 620 ACAATGGGCATGCTGCTGCTACTGCTGCTAAGTCGCTTCAGTCGTGTCCGACTCTGTGCnACCCCATAGACGGCAACCCACCAGGCTCCCCCGTCCCTGGGATTCTCCAGGCAAGAACA A G 621 GTCGCTTCAGTCGTGTCCGACTCTGTGCGACCCCATAGACGGCAACCCACCAGGCTCCCnCGTCCCTGGGATTCTCCAGGCAAGAACACTGGAGTGGGTTGCCATTTCCTTCTCCAGTG A C 622 CAACCACTTGCATAAAAGTAATAGAAACACAATGGGGACTTTTTTTTTTCTTTTTTTTTnAATTTTATTTAATTTTTAAACTTTACATAATTGTATTAGTTTTGCCAAATATCAAAATG T A 623 ACAAATAATAAATGCTGGAGAGGGTGTGGAGAAAAGGGAACCCTCTTACACTGTTGGTGnGAATGCAAACTAGTACAGCCACTATGGAGAACAGTGTGGAGATTCCTTAAAAAACTGGA G A 624 CAAATAATAAATGCTGGAGAGGGTGTGGAGAAAAGGGAACCCTCTTACACTGTTGGTGGnAATGCAAACTAGTACAGCCACTATGGAGAACAGTGTGGAGATTCCTTAAAAAACTGGAA G A 625 AGACTCTTGAGAGTCCCTTGGACTGCAAGGAGATCCAACCAGTCCATCCTAAAGGAGATnAGTCCTGGGTGTTCTTTGGAAGGAATGATGCTACAGCTGAAACTCCAGTACTTTGGCCA C T 626 TCTATACCCTGTGTGAAAACAGATCTGTCTCTAAGTACCTGCTGCTGCTGCTGCTAAGTnGCTTCAGTCGTGTCCAACTCTGTGCGACCCCATAGATGGCAGCCCACCAGGCTCCTGCG T C 627 ATCCCCCCACCCTTTTCTTTTCCTGGCTGCACCATGTAGTACGTGAGATCTCCGTTCCCnGATAAAGGATTGAACCCGCACCCTCAGCAGTGAAAGCTCAGAGTCCTAACCGCTAGACC T C 628 GAGTTGAATTCTCTGTCACCGCATGGTATCTGCACATTGCTAGCTGGTGGGGGGAAGCCnACACACACACACACACACTTTGGAATTTGGTCCAGGAACCTTTTTCAGTCGCACGCCTA TACACA T CACACA CACACA CACACA CACACA C 629 TTTTTAACATGGCAATTAGAACGTTTAACGTCACATATGTGGCTGGCATTCTATTTCTAnGGAACCACTCCAGGCTAAGGACTCTCCATTTTAACCAGTACCTTGAAACATTCTGAAGC C T 630 GAATACGGTGGTTCAAAGCCAGAGGGTGGGTTCCCAGGGATGGAGGGGATGACAGTGGGnGCGTACCAGGGTATGGGTTTGGGCCAGCAGCCAGCTCAACTCCAAGGACTCGGTCTCTG T C 631 GGCTCAAGTCGCTCCAGCTGGTCCCTGGCTCATGGACTGCACCCCTCCTTCTCTGTCTCnGTTTTCACATTCACATGGCCATCATCTCTGTGTGTCTGTGTCTCTGTCCAAATTTCCCT T C 632 CCTTGCTCACGGATCTCAGAGGGGAGATGAGTAACAAACACACACACGTGGGAGAAGGAnAGGAGGTGGAAGAATGTGAGTGTGAGAACTGAGCATGAGGTTCCTCACACAAGGTGGTT C T 633 AACCAAGCATGGGAAAGACAGGAGCAGGCAAAGGGCTGGGAAGATCGTCCCCAGCAGGGnACAGAGACTGGAAGGCGTCAAGCTGGGTATGTCCAGGGGCTAGGCAGCATCCTTGGTGT AAC A 634 GGCTGGGAAGATCGTCCCCAGCAGGGAACACAGAGACTGGAAGGCGTCAAGCTGGGTATnTCCAGGGGCTAGGCAGCATCCTTGGTGTGAACTTTGTCAATTGAAAGTGCATCAGGAAA A G 635 GCTAGGCAGCATCCTTGGTGTGAACTTTGTCAATTGAAAGTGCATCAGGAAATCACTGGnCAGTTTTAACGAGAGTGACTTAATCTGACTTTTACATTTTGTTTTTTTAAAATCACTAA A G 636 TGTGTTTGTTAATCAGGTGGTTCTGAAAAGCCTCTAAAAATGTAGGCTGGTTGCCAAGGnAACCAACTTGGTTATTAGAGGGTTGAGCCTTTCGATTGACCCTCCTGACCTCTTGGGAG A G 637 TGGGACTAAGCCTTTGACCCGTAGGATCAGATGCTACCTCCAGGGAGGCAGGGTCAGAAnTGAGTTCAATCTGGGCCTGGAGGTTTTGCAAACAACGTGGTTCACACTGATATATGCTT A C 638 CCCTTCTCCAGGGGATCTTCCTGACCCAGGGATTGAAGCCAGGTCTCCTGCATTGTAGGnGGATTCTTTACCATCTGAGCCAACAGGCAAGTCTAGGGACAGACAAGTTGGCAATACCC T C 639 AACCCCAGGGCTTGGCCAAATCGCCCTGTGGATTAATGGAGCATAGGACTAGCTTGGGGnGCCAAGAACCAAGTGAATATGGTCAAATCTCCCTCCTGGACTTCCCTGGTGGTCCAGTG T C 640 GAAGCCCATGAGCCCTAGAGCCCGTACTCTGCAAAAAGAGAAGCCACTGCAATGAGAAGnCTGCACACTGCAGCTAGAGTAGCCCCAGCTCTCGAAACTACAGAAGAGCTGCCTGCAGC G C 641 CCAGAAGCCCTCTGCAAAAGTGCTCACTACACTTCTGATTACTCCCAGAGCCCTCTGCTnACTCTTGTCAAAGTCCCTGCCTGAATTCTCATTTCTAAATGGTGAAGGTGTTGCAACCA T G 642 CCTGAATTCTCATTTCTAAATGGTGAAGGTGTTGCAACCAACCTATTTCACCCAGAGGCnGGGTGCTGCTGCATGGGAGCAACTCTAAAGGGCGAGAACGGCGGTTCTCACAGTTGAGT T C 643 CAACCAACCTATTTCACCCAGAGGCCGGGTGCTGCTGCATGGGAGCAACTCTAAAGGGCnAGAACGGCGGTTCTCACAGTTGAGTCCCATCGTCACATCTCGGGCACGTGCAAACGACA A G 644 AACCTATTTCACCCAGAGGCCGGGTGCTGCTGCATGGGAGCAACTCTAAAGGGCGAGAAnGGCGGTTCTCACAGTTGAGTCCCATCGTCACATCTCGGGCACGTGCAAACGACAGAGAC T C 645 ACAGGGACTTCCTGGTGGTCCAGCAGATAAGACGACTCTGAGCTGCCAATGCAGGGGGGnCAGGGTTTGATTCCTGGTCAGGGAACTAGGATCCTGCCTGCCCTGCAGTGTGACCAAAA A C 646 TAGCACTCAAGCTTAGTTGCCCTGTGGCATGTGGAATCTTATTGGACCAGGGGTGGAACnCATGTCCTCTGCATTGGCAGGTGGATTCTTAACCACTGGAGCACCAGGGAAGTCCTCAA T C 647 GATGTATCATTTACATACTATAAGGTTCTCGTCTTTAAAATGCATGATTCAGTGTTGTTnTTTTTTTTTAAAAAATCCCCCATAATTGAATTTTAGAACATCTTCATCTCCCCAAAAGG G GT 648 CCCTGGGATTCTCCAGGCAAGAACACTGGAGTGGGTTGCCATTTCCTTCCCCAATGCATnAAAGTGAAAAGTGAAAAGTGAAAGTGAAATCGCTCAGTCATGTCCGACTCTTAGCGACC G GAAAGT GA 649 TGTCCGACTCTTAGCGACCCCATGGACTGCAGCCTACCAGGCTCCTCTGTCCATGGGAGnTTCCAGGCAAGAGTACTGGAGTGGGTTGCCAGTGCCTTCTCCCTCTCAGCCTAGGCAAC C T 650 GAGTGGGTTGCCAGTGCCTTCTCCCTCTCAGCCTAGGCAACCACTAATCTTCTTCCCGTnTCCACGGTTTTGCCTTTCCTGGACTTTCTGTACAAATGAAATCAGGCAATCCGTGACCT T C 651 GTTTTGCCTTTCCTGGACTTTCTGTACAAATGAAATCAGGCAATCCGTGACCTTTTGTGnCTGGCTTCTTGCACTCAAAATAATAATGTCTGGCTTCACCCATGTGGCTGCGTGAATCA A C 652 TCTTGCCAAATAGCACTCCCTTCCAGGGTTCTCCACGCTTTGTTCCTCCTCTCGTTATTnTTTAAAAGCATCACAGTTTGTGCCCATTTGTCCATAGGTAGCAATTTTTACATTTTGTT C T 653 CTATTTTGGGAAGAAGGGACATTACAGCTTCTGCTGCCGCTGACCTTCTCTGTGCCTTAnTTCTCAGCTGTAAAATGGGACTGAGGAAGAATGGACATTAGGGAACTTCCCTGTCCACC GT G 654 GCTCAGAGGAAAGGTGAGGCCCACCTTGGGGACCAGCCAGGGCAGGAAAGGGTGATACAnGGAAAGGCTCATCGGGGGCCTTTTGGACCGGGTGGGTGGGAACACTCTGCCCCCTGGGG C T 655 TGAGGCCCACCTTGGGGACCAGCCAGGGCAGGAAAGGGTGATACATGGAAAGGCTCATCnGGGGCCTTTTGGACCGGGTGGGTGGGAACACTCTGCCCCCTGGGGCTGGCACCGCTCAC A G 656 CCTGGGGCTGGCACCGCTCACTGTGGCTTCTGCTCCAGCAAGTTAGTCCTTGGCTCCCTnTCTGTGTGAAGACACAGGAGCCCTGAGGGGATGCTGTGGGCAGCACTGTGTTCCTCCAC C G 657 GTCTGTGTGAAGACACAGGAGCCCTGAGGGGATGCTGTGGGCAGCACTGTGTTCCTCCAnATCTCAGTGAAGGTGAACTGAGGCCAATGTGGAGGACCTGGATCCAACAGGACTGGGGG A C 658 GTGTGAAGACACAGGAGCCCTGAGGGGATGCTGTGGGCAGCACTGTGTTCCTCCACATCnCAGTGAAGGTGAACTGAGGCCAATGTGGAGGACCTGGATCCAACAGGACTGGGGGCCCT C T 659 GCACTGTGTTCCTCCACATCTCAGTGAAGGTGAACTGAGGCCAATGTGGAGGACCTGGAnCCAACAGGACTGGGGGCCCTACAAGAAGAGATGGGGGGCTTCCCCACAGGTCCCCCAGT C T 660 GGACCTGGATCCAACAGGACTGGGGGCCCTACAAGAAGAGATGGGGGGCTTCCCCACAGnTCCCCCAGTGGTTAGAACTCGGTGTGGTCAGTGCTACAGGCGCAGGTTCAGTCCTGGTC G GT 661 GGGCTTCCCCACAGGTCCCCCAGTGGTTAGAACTCGGTGTGGTCAGTGCTACAGGCGCAnGTTCAGTCCTGGTCAGAGAACTAGGATCCCGCATGCTGAGCAGCGTGGCAAAAAAAAGG C G 662 CCCACAGGTCCCCCAGTGGTTAGAACTCGGTGTGGTCAGTGCTACAGGCGCAGGTTCAGnCTGGTCAGAGAACTAGGATCCCGCATGCTGAGCAGCGTGGCAAAAAAAAGGTTAACACT TC T 663 TGGTCAGTGCTACAGGCGCAGGTTCAGTCCTGGTCAGAGAACTAGGATCCCGCATGCTGnGCAGCGTGGCAAAAAAAAGGTTAACACTGCATTTGATGGGAAAAAAAATTTTTTTTAAA T A 664 AGGTTCAGTCCTGGTCAGAGAACTAGGATCCCGCATGCTGAGCAGCGTGGCAAAAAAAAnGTTAACACTGCATTTGATGGGAAAAAAAATTTTTTTTAAAAGAAAGAAAATGAACCCAC A G 665 TGAGCAGCGTGGCAAAAAAAAGGTTAACACTGCATTTGATGGGAAAAAAAATTTTTTTTnAAAGAAAGAAAATGAACCCACTCCAGTCTTCTTGCCCAGGAAATCCCATGGACGAAGGA A T 666 TTTTTAAAAGAAAGAAAATGAACCCACTCCAGTCTTCTTGCCCAGGAAATCCCATGGACnAAGGAGCCTGGTGAGCTACAGTCCAAGGGGCTGCAAAGAGTCAGGCACCACCATGCCCA A G 667 CTTGCCCAGGAAATCCCATGGACGAAGGAGCCTGGTGAGCTACAGTCCAAGGGGCTGCAnAGAGTCAGGCACCACCATGCCCATGTTTAACTGAATCTCTGCTGTACACCTGAAACTAA G A 668 GTTCAGTGAAGCCCAGAGCCTGAAGCAGTTCACAGAAATAGGTGAAAAGCCAAACCAACnGCACAGGTTGTATGTTTTTTCTACAACCTATAAAATATAGCCAAAATTTTATAGTAACT A G 669 ATTTTATAGTAACTATAAATGAAGTATAACCTATAAAAAGTGTGAATGTTGTATACCGCnAACAGCACTGTATAATCATATACTACTGTACATCAACTCTACCTCAATTCAAAAATGTA A G 670 GGTTCATCATACAATTCTTTCTCCCTTTGTGTCTCCTGGGCAATATTCAGGATGAACAGnTAAAATGAAAAAGATTCAAGTGAGCCAACTCAGGAGGCCCGCGGCCATGGCCAGTCCAA A C 671 GGCCATGGCCAGTCCAAGGGAGAAGACACAATTACTCCAGCTCAGCATTTCATCACCCCnTCCTAAATCTGGAGGGCATCCTAAACTCTCCTCACCCCCATTACCCCCAAGCATATTTA G A 672 GCTGGGTAACTGAGGTACCATGTGATATATGCTGAGGCCAAAAAGTAAGATAAACCACGnGGAGAAACCATGTCAGTCCTACTAGAATGGTTACACTCAAAAAGTGTAACCTACGTCAA A G 673 GAGGTACCATGTGATATATGCTGAGGCCAAAAAGTAAGATAAACCACGGGGAGAAACCAnGTCAGTCCTACTAGAATGGTTACACTCAAAAAGTGTAACCTACGTCAACAGGTGAATGG T C 674 CAACTCTGAGCTTCCACTGCACGGGGTGCAGGTCCTGGTTGGGGAACTAGGACCTGACAnGCTGTGAGGCAAGGTCAAAGAGAAAGACAACTACTGTATGATAACACTTTGTGGGGAAT C T 675 AGAGGCAGACTCACAGATACAGAGAACAAACTAGCGGTTACCAGCAGGGAAAGGAAAGAnGGGGGATGGACAAGATAGGGGTAGAGGCTAAGAGATACAACTACTATGTATAAAGTAAG T A 676 TGCTGATAGGAACGTCAAATGGTCTGAACAGAAACTCCTTGAGATGTCAGAGCTGCCATnTGCTGTGCCGTGTGCTTACTCACTCAGCTGCCCAACTCTTTGCGACCCCATGGACTGTC A T 677 AAACATTTTGGACCCTAACTTGATGTGACCTCCACATCTAACTCACAGTTTACAGGAAAnATGGGGGATGGAAGCAGAAAAATTAGAAACAGCAGAAGCTAAAGTCAGAATGTGGAACG C T 678 TACCCAGGTCAAGAAAAGGAACATTATCAGTTTTGCCAAAAGGCTCCCTTTGCCCTCTCnTGTTCACTACACCCCCTCCAAAATTTAGGGGATTCATTTTGCCTGTTTTTGAACTTCTG T C 679 TCTCCTCCTGTCTTCAGTCTTTCTCAGCATCAGGGTCTTTTTCAATGTGTCAATTCTTCnCATCAGGTGGCCAAAGTATTGGAGCTTGAGCTTCAGTATCAGTCCTTCCAATGAATATT T G 680 GAATATATAGAATATTTTGCATACATTCATACTAAACAGATAAAGTACAAGAGGTGTTTnGTGAGTTGCAGAGTTTCGTGCGATACAGAGGGAAGACCCCATTGAGAAAGCATTGGATC A G 681 TGCATACATTCATACTAAACAGATAAAGTACAAGAGGTGTTTGGTGAGTTGCAGAGTTTnGTGCGATACAGAGGGAAGACCCCATTGAGAAAGCATTGGATCCTTAAGACCTGAGGGCC C T 682 CGATAGGGAAAGTATCTTCTGGGATAAGAGCTCGGTGACCAGCTGAGAACAGGGGGGCCnTCCCATACTGAGAACTGCGTGAGCAAAGGCCCTGAGGCAAGAGGGCGCATGGGTCTCAG G A 683 TAACAGACCTTGAAGTGCCACTGGCTTCACGCCACAAAGGTTTCCTTGTAGGTGATGTCnACCCACTGGCAAGTGGGGGGTATGGGATTCTGGTCCACACACTGATTCAGCGACCCAGG AGAGCC A T 684 CTCTTTCCCATTGCTCCTTTGGCACTGCCCACTTCCTCCTGGCCACCCTCTGGCTTCACnGATCCTCACAGTCCACCCACCGCCACCCTGCCCCCGGCGGCCTCCCGCTTCAAGCCCTG C T 685 GCACTGCCCACTTCCTCCTGGCCACCCTCTGGCTTCACTGATCCTCACAGTCCACCCACnGCCACCCTGCCCCCGGCGGCCTCCCGCTTCAAGCCCTGACAGTGTCCCGGCCCTCCCCC T C 686 AACACTATCCTCGCCCACCCGCCCCCCTGGGTGCCAGAGACTTGCTGACTCCTGCCAAAnTCGGCATGGTCACCCCCTGCCTCAGGGCCAAACTACGGCTCCAGCAGCACTGACTGGTC T G 687 CTGGGTGCCAGAGACTTGCTGACTCCTGCCAAAGTCGGCATGGTCACCCCCTGCCTCAGnGCCAAACTACGGCTCCAGCAGCACTGACTGGTCCAGCCACTGTCACCCCTTGGGTCCTC A G 688 ACAGCTTCACTGTAGCAGCAGCAGCAGCAAAGACTGTCAGCACCCCTCACGGGCCCCAGnGCAGCAGCATCCAGACCACAGGAAGTCCCCAGGACCACTGGCTGACGATGGGCCTTCAG C G 689 CTCTTAACAGGAAACTGAAAGCAGACCCTGTGCCTGTGGGCTCAAACGCTGGTGGGAGCnCGCCTACCCCGGGTCAGCCAGGTTTCTGCCCCCAAGTCTGTCACTGAATCTTTCTCCGC T C 690 GCAGACCCTGTGCCTGTGGGCTCAAACGCTGGTGGGAGCCCGCCTACCCCGGGTCAGCCnGGTTTCTGCCCCCAAGTCTGTCACTGAATCTTTCTCCGCATTTCCAGCCTGGATGGGAA G A 691 TCTGCCCCCAAGTCTGTCACTGAATCTTTCTCCGCATTTCCAGCCTGGATGGGAAGGGCnTTTGGGGGAGAACGGATCCATGTATGTAGATGGCTGAGTCCCTTCCCTGCTCACCTGAA A G 692 TGAAACTATCACAACATTGTTAACTGGCTACACCCCAACACAAAACAAAAAATTCGAAAnAAAAACTTCCTCCACTTTTCATACTGTTAACCTTTCCTGTTTTCAACTTTGTTTTTCCT GAAAAA G A 693 CTCTTTTTTTCAAAATGCTTCAGTTATATCAGGCACATAAAAATGTATAGATAATCTCAnAGCAAACTTCAATGCTCACTACCTAGGTTGGTTTGGGGGGCTGCTTTGCTTTTTCCCTC A C 694 TTATATCAGGCACATAAAAATGTATAGATAATCTCACAGCAAACTTCAATGCTCACTACnTAGGTTGGTTTGGGGGGCTGCTTTGCTTTTTCCCTCCCTCCTCCTCCTACACATTCACT T C 695 GCTTTTTCCCTCCCTCCTCCTCCTACACATTCACTACATGTGTATGTCCATTTATAATAnAGATATATGTTTTTCATGCTTTTAAATTCTATGTAGATGGACCCATAGTCTAGGTATCC T C 696 CTTTTTCCCTCCCTCCTCCTCCTACACATTCACTACATGTGTATGTCCATTTATAATACnGATATATGTTTTTCATGCTTTTAAATTCTATGTAGATGGACCCATAGTCTAGGTATCCT G A 697 ATGTTTTTCATGCTTTTAAATTCTATGTAGATGGACCCATAGTCTAGGTATCCTGATATnACCTGGTTTTTTTTAGCCCAACACTTTATGAGTTTTATCCACGTTGATATAGACACTCT C A 698 ATATTCAAATCATGTAGGGTACTGAATAAATAATGGAAACCTCCCTTTACCTACTTCTCnATCTCAAAATTTACCACCATGACCACCTATGTGTATTCTGCCAGCCCTTTTTCTAGGCA C T 699 TAACTCCAGTGTCTGCTGGATAAAAGCCACACTCCCCATTCTGGCACTCAGGGCCTCGTnTCTCAGTTCCCCAGTCCTCAGGCAGCCTGTACAGGGTCTTACTGAACCAGCGTTCCTCT C G 700 AAGCCACACTCCCCATTCTGGCACTCAGGGCCTCGTGTCTCAGTTCCCCAGTCCTCAGGnAGCCTGTACAGGGTCTTACTGAACCAGCGTTCCTCTGAGAGCCCACGTGTTCCAGACCT G C 701 CTGGCACTCAGGGCCTCGTGTCTCAGTTCCCCAGTCCTCAGGCAGCCTGTACAGGGTCTnACTGAACCAGCGTTCCTCTGAGAGCCCACGTGTTCCAGACCTCGGTCAGAGAGAGCAGG C T 702 GCCTCGTGTCTCAGTTCCCCAGTCCTCAGGCAGCCTGTACAGGGTCTTACTGAACCAGCnTTCCTCTGAGAGCCCACGTGTTCCAGACCTCGGTCAGAGAGAGCAGGACAGGGGTCAAT A G 703 GTGTTCCAGACCTCGGTCAGAGAGAGCAGGACAGGGGTCAATCCTGAGTCTCATGCCCCnCCCGCACTAGCCAAGTTAGCCCGCTCATGGGTGCCACTTCCACTTCTGAGAGGCTGGCT A G 704 GAGCAGGACAGGGGTCAATCCTGAGTCTCATGCCCCGCCCGCACTAGCCAAGTTAGCCCnCTCATGGGTGCCACTTCCACTTCTGAGAGGCTGGCTCCAGTGTCCTCCCTGACTTGAGA A G 705 CTGCAGACAGTGGGGTCTGGAGGCCTCACTTGGTAGACAAAGGATGGTGCATTATAATTnTGTTTTCACTTAGCAGTTCACTTCTCTGCCACACTCGCTAACTAAGATCCAGGAAGAAA C A 706 ATGCCAATTGGATTCATGAGCTTCGCCTCTCCCACTAATGGGGTCAGGCTCTGGCGGCCnTTATTGCACAGAGGCTCCGGGAGAAGCAAACACACAGGCGAGACTTCACCGCCACTTAT T A 707 AGGGCTGCGCAGAACCCACATTCCCTAATGTGGGGGATCGACATACCTCCCTCAGCATCnAGGCCTGAAGCTTCTGAACCCTGACTTTAAGGCCGGGCACACTGAAACTTGTCGGAGAG T C 708 TCGACATACCTCCCTCAGCATCCAGGCCTGAAGCTTCTGAACCCTGACTTTAAGGCCGGnCACACTGAAACTTGTCGGAGAGACCTAGCCACAGGGAGTTCCTAGTCTGAGAGAAACCC T G 709 GAAGTAAGTATATTATTATTCCTATTTTATGGTGAAGGTCAGAAAGGTTAGATGTCTGAnTTTACACACTGTTAAGTGATGGGGTCAGAATTCAAACCCGGAGTCATCTTAGACACTAC A G 710 GTATATTATTATTCCTATTTTATGGTGAAGGTCAGAAAGGTTAGATGTCTGAGTTTACAnACTGTTAAGTGATGGGGTCAGAATTCAAACCCGGAGTCATCTTAGACACTACACTTTGC T C 711 AGTGATGGGGTCAGAATTCAAACCCGGAGTCATCTTAGACACTACACTTTGCTTCTACTnTTTTTTTTTCCCCTAATAAAAGTCTTTTTTCTTCAATTAATTTGCTTCTCTTGACTTCT CT C 712 GAAGTCCCAGGGCCATAGGCCTGGGCCAAGAAGCACCTTTGATGGTGGGTGAGGGGTCTnATGAAAAGGGCAAGAAAGGAACTGTTTTCAATCATTCTCAGGACGCAAGAATTTCTGGT G C 713 CAAGAAGCACCTTTGATGGTGGGTGAGGGGTCTCATGAAAAGGGCAAGAAAGGAACTGTnTTCAATCATTCTCAGGACGCAAGAATTTCTGGTACTGGGCCACCTATACCTTCAGGCCC C T 714 GTGGGTGAGGGGTCTCATGAAAAGGGCAAGAAAGGAACTGTTTTCAATCATTCTCAGGAnGCAAGAATTTCTGGTACTGGGCCACCTATACCTTCAGGCCCTCTCAGAAATCCTTGGGA T C 715 CCACCTATACCTTCAGGCCCTCTCAGAAATCCTTGGGATATTATTGACAGGCAACAAACnCCGCCAAATTGTCTGCCATGCCTACACAATGTGTGGGCACAGAGGGTTATGGCTTCATT G A 716 AATTGTCTGCCATGCCTACACAATGTGTGGGCACAGAGGGTTATGGCTTCATTTGCTCCnTCTATAATCCATGTGTAGAGACCCTCTTTTCCGAACCCAAAGTGTTCTGTCTAGGTCAA G A 717 CAATGGATGAATGCATTAATGTAATCTCAAAGATTCGCAGTGAAACTAAGCCATTGCCGnTGAAAGGGTCCAAGCCCAGGGTGCAAAGATTATTGCCCCAATTCCACACTCCGGGCTAC C G 718 TAATGTAATCTCAAAGATTCGCAGTGAAACTAAGCCATTGCCGGTGAAAGGGTCCAAGCnCAGGGTGCAAAGATTATTGCCCCAATTCCACACTCCGGGCTACTTGTACCAGGAACCAC A C 719 CGGGCTACTTGTACCAGGAACCACCCTGCCCCCTCCACTGGAACGACCACGCTGCGCATnCCAGGGAGGCTCGCCTCCTCTGGCGGCCCAGCTTCCCTTTCTCCTCGCGTCTTTCTGTC C T 720 TCGGGATTTTCTCTCCCTTCTTCCTGCCGCCCTCTCCTCTACCCTGTGACCCCTGCCCCnTCCCCGCTGTGCCCCCACCACACTCTGTCAAACTGGGGCCAGGAGACCAGCGCTAAGGT C G 721 AAGGTCACTGGGTTTCAACCTGCAGAATGGGAAGCCATCTCCCCTGTCTACAGGTGAATnCTGTTACTCTGCCTCCAGCCATGGACTGCTTGCTCTTGTGGGAAAGTGGAAAGCAGCTG T G 722 CAGGTGAATGCTGTTACTCTGCCTCCAGCCATGGACTGCTTGCTCTTGTGGGAAAGTGGnAAGCAGCTGACCAGGGACCGGGGATGCTAGTCAACCAGTAATTCTCAGTGTAACCTAGA G A 723 AGTCCCTAAACTATCAGGTTGGGATTCACCAAGGAGATTCCTGAAAAGGAGAGAAAGTAnCGTGGCCTTGCCTAAACCTCCACATTTGCCCTTATAACATCTCTGCCTTCACTGGCCTG G A 724 CTAAACTATCAGGTTGGGATTCACCAAGGAGATTCCTGAAAAGGAGAGAAAGTAACGTGnCCTTGCCTAAACCTCCACATTTGCCCTTATAACATCTCTGCCTTCACTGGCCTGGGCGT T G 725 AAAAGGAGAGAAAGTAACGTGGCCTTGCCTAAACCTCCACATTTGCCCTTATAACATCTnTGCCTTCACTGGCCTGGGCGTGGAGTGATTGCATGTTTCTTAAGGACCCACTGTGTGCC C CT 726 TCTGCCTTCACTGGCCTGGGCGTGGAGTGATTGCATGTTTCTTAAGGACCCACTGTGTGnCAAGCACGCATATATCACAGCCCCACTCTCAGAGCGCTCGTGGCATAATAGAGCAGCGT T C 727 CACTGGCCTGGGCGTGGAGTGATTGCATGTTTCTTAAGGACCCACTGTGTGCCAAGCACnCATATATCACAGCCCCACTCTCAGAGCGCTCGTGGCATAATAGAGCAGCGTGGCAGGGC A G 728 GGGGGTGAAGCTTCATGCCAGGCTGTACTGCACAATGAGAGAGCGAGGGCCAGGTTCTGnCTGCACTCCCCCGGTCAGCAGCCTCCTCAGCGCAGGACACGACCTGCTCAGCCTCTGAC T C 729 TATCCTGTATGGGAACAGGTGGGGAAGCTGTCTGCAGGCAAGAAATGGGCAGACTGAGGnCATGGAGCACAGCCTTCTCTCCCCTCCACCTCTTGCTGGCACAAGCAAACTGAATGCAG G A 730 CTATAATAGTTAATGGGTATTAAATATTTACCATCATGCACTGTGCTAAGTGCCCCACAnGCATTATCTAATTTCATCCTCAAACAACTTTGGAAATACGTGCTATTAATAATCTCATT T C 731 ACTGTGCTAAGTGCCCCACACGCATTATCTAATTTCATCCTCAAACAACTTTGGAAATAnGTGCTATTAATAATCTCATTTTACTGATGAGGATTCTACGTAACATGCCTAAGGTCACA T C 732 CTCAAACAACTTTGGAAATACGTGCTATTAATAATCTCATTTTACTGATGAGGATTCTAnGTAACATGCCTAAGGTCACACAGCTATTTAGTGAGGGCCCTGGGGATGGAATTCACAGC A C 733 GTTCTATATCTGTTGGACTAAGTGGAGAAGGGCTCTGAATTCCATGCTAGGGAGCTTGAnCTTTACACCATGGGCAATGGGGAGACACTGGACGGTTGTAAGCAGGGAGAGACGGGTCA C A 734 GAGCAAGAGGCCATTTTTCTGGCAAATCCCAATTCCTCCTTGTATTTTTTTTAAGTCTTnTCTTATCTCTTAGGGCAAGACTTATACGCACAGTACATCATGCAAAATGCTGGACTGGA A G 735 AGCAAGAGGCCATTTTTCTGGCAAATCCCAATTCCTCCTTGTATTTTTTTTAAGTCTTGnCTTATCTCTTAGGGCAAGACTTATACGCACAGTACATCATGCAAAATGCTGGACTGGAT C T 736 GGATGAAGCATAAGCTGGAACCAAGATTGCAGGGAGAAATATCAGTAACCTCAGATATGnGGATAAGTAACCTCAGATATGCGGATAACACCACCCTTATGGCAGAAAGCAAAGAGGCA T C 737 AGAGCCTCTTGATGAAGGTGAAAGAGGAGAATGAAAAAGCTGGCTCAAAACTCAACATTnGGAAAACAAAGACCATGGCATCGGGTCCCATCACTTCACGGCAAATAGATAGGGAAACA C T 738 GAAGGTGAAAGAGGAGAATGAAAAAGCTGGCTCAAAACTCAACATTTGGAAAACAAAGAnCATGGCATCGGGTCCCATCACTTCACGGCAAATAGATAGGGAAACAATGGAAACAGTGA T C 739 GAGGAGAATGAAAAAGCTGGCTCAAAACTCAACATTTGGAAAACAAAGACCATGGCATCnGGTCCCATCACTTCACGGCAAATAGATAGGGAAACAATGGAAACAGTGACAGACTTTAT A G 740 ACTCAACATTTGGAAAACAAAGACCATGGCATCGGGTCCCATCACTTCACGGCAAATAGnTAGGGAAACAATGGAAACAGTGACAGACTTTATTTTCTTGGGTTCCAAAATCATTGCAG G A 741 AAGAAAAGCTATGACAAACTTAGCCAGAGGCATTATTTTGCTGACAAAGGTCTGTCTAGnCAAAGCTATGGTTTTACCAGTAATCATATATGGATGTGAGAGTTGGACTATAAAGAAAG T A 742 GACAAAGCTATGGTTTTACCAGTAATCATATATGGATGTGAGAGTTGGACTATAAAGAAnGCTGAGTGCCAAAAAATTGATCCTTTTGAACTGTGGTATTGGAGAAGACTCTTAAGAGT G A 743 GGTTTTACCAGTAATCATATATGGATGTGAGAGTTGGACTATAAAGAAAGCTGAGTGCCnAAAAATTGATCCTTTTGAACTGTGGTATTGGAGAAGACTCTTAAGAGTCCCTTGGACAC G A 744 TTTACCAGTAATCATATATGGATGTGAGAGTTGGACTATAAAGAAAGCTGAGTGCCAAAnAATTGATCCTTTTGAACTGTGGTATTGGAGAAGACTCTTAAGAGTCCCTTGGACACCAA G A 745 GAAGCTCCAATACTTTGACCACTTGATGTGAAGAACTGACTCACTGGAAAAGACCCTGAnGCTGGCTGGGAAAGATTGAAAGCAGGAGGAGAAGGGGATGACAGAGGATGAAATGGTTG T TGCTG 746 TCACTGACTTGATGGACATGAGTTTGAGCAAGCTCTGGGAGTTGGTGATGGATAGGGAAnCCTAGCGTGCTGCAGTCATGGAGTCTCAAAGAGTCAGACAGGACTGAGCAACTGAACTA A G 747 CCCTTCTCTGGGCAGCTCATGATATCACTGGCTTTTCCAGCAAGTGGGGTGGGGAGTTAnAGGAAATGGCCTGGGGCATCAGATAAGCTGAAGAAAGAGGCCGAGTAGCTGGAAAGACG G C 748 GGGTCCCAAGATGCTGCTCTGCGTCACCTTGCTTCTCCTCCTGGGGCTGTCTGCATGCAnTGTGGCAGGTGACAAGGAACTGGCAATCAATGCTGAAGTTGGCTCCTGGGTGGCTGTGA T C 749 CCTTGCTTCTCCTCCTGGGGCTGTCTGCATGCACTGTGGCAGGTGACAAGGAACTGGCAnTCAATGCTGAAGTTGGCTCCTGGGTGGCTGTGACCCTGGAGGTAGGTACCTTTGGGGAA G A 750 AGGTAGGTACCTTTGGGGAAAGCAGGGCATGATAGCAAGAGAGCAGGCTGTACACTGCAnGGTAGGGTGTCTGCCTCCCCTCTCTGGGCATGTTCAAGGCTGTTGCCCCTGGCCTGATA C T 751 TCAGGCTTCCCTGTCCTTCACCATCTCCCAGAGCTTGCTCAAACTCATGTTCATCAAGTnGGTGATGCCATCCAACCATCTCATCCTCTGTCCCCTTCTCCTCCTGCCTTCAATCTTTC C T 752 GAGCTTGCTCAAACTCATGTTCATCAAGTTGGTGATGCCATCCAACCATCTCATCCTCTnCCTTCTCCTCCTGCCTTCAATCTTTCCCAGCATCAGGGTCTTTTCCAGTGAGTCAGTTC GTCA G 753 CTCATCCTCTGTCCCCTTCTCCTCCTGCCTTCAATCTTTCCCAGCATCAGGGTCTTTTCnAGTGAGTCAGTTCTTCACATCAGGTAATCAAAGTATTGGAGCTTCAGCTTCAGCATCAG T C 754 CCTTCAATCTTTCCCAGCATCAGGGTCTTTTCCAGTGAGTCAGTTCTTCACATCAGGTAnTCAAAGTATTGGAGCTTCAGCTTCAGCATCAGTCCTTCCAATGAATATTCAGGACTGAT G A 755 ATATTCAGGACTGATTTCCTTTAGGATTGACTGATTTGGTCTCCTTGCTGTCCAAGGGAnTCTCAAGAGTCTTCTTCAATACCACAGTTCAAAAGGATCAATTTTTTGGCACTCAGCCT G C 756 TCCTTTAGGATTGACTGATTTGGTCTCCTTGCTGTCCAAGGGACTCTCAAGAGTCTTCTnCAATACCACAGTTCAAAAGGATCAATTTTTTGGCACTCAGCCTTCTTTATAGTCCAACT C T 757 CCAAGGGACTCTCAAGAGTCTTCTTCAATACCACAGTTCAAAAGGATCAATTTTTTGGCnCTCAGCCTTCTTTATAGTCCAACTCTCACATCCATACATGACTACTGGAAAAACCATAG G A 758 GTCCAACTCTCACATCCATACATGACTACTGGAAAAACCATAGCTTTGACTAGACAGAAnTTTGTCAGCAAAATAATGTCTCTGCTTCTTAATATGCTGAGTTTGTCATAGCTTTTCTT C T 759 AGACAGAATTTTGTCAGCAAAATAATGTCTCTGCTTCTTAATATGCTGAGTTTGTCATAnCTTTTCTTCCAAGGAGCAAGCATCTTTTAATTTCATGGCTGCGGTCACCATCTGCAGTG C G 760 TGTCACTGTTATCTATTTGCCATGAAGTGATGGGACCCAATGCCATGAACTTTGTTTTCnAATGTTGAGTTTTGAGCCAGCTTTTTCATTCTCCTCTTTCACCTTCATCAAGAGGCTCT G A 761 ATACAGGTTTCTCAGGAGGCAGATAAGGTGGCCTGGTATTCCCATCTCTTTAAGAATTTnCCACAGTTTGTTGTGATCCACACAGTCAAAGGTTTTAGCGTAGTCAACGAAGCAGAAGT T C 762 AAATCCAGCTTAAACATCTGGAAGTTCTCGGTTCACATACTGTTGAAGCCTAACTTGGAnAATTTTGAGCATTACTTTGCTAGCATGTGACATTAGTGTAGTTGTGCGGTAATTTGAAC G A 763 TTAGTGTAGTTGTGCGGTAATTTGAACATTCTTTGGAATTGCCTTTCTTGGGATTGGAAnGAAAACTTTTTCCAGTCCTATGGCAACTGCTGAGTTTTTCCAAATTTTCTGGCATATTG T C 764 TGGAACGAAAACTTTTTCCAGTCCTATGGCAACTGCTGAGTTTTTCCAAATTTTCTGGCnTATTGAGTGCAGCACTTTCACAGCATCATCTTTTAGGATTTGAAATATCTCAACTGGAA G A 765 AGATGTCTAGTCTTTCCCATTCTATTGTTTTCCTCTATTTGCATTGATCACTTAAGAAGnCTTTCTTATCTCTCCTTGCTATTCTCTGGTCTCTGCATTCAGATGGATATATCTTTCCT G C 766 TTTTCTTGGGGATGGTTTTGATCACCGCCTCCTATACAATGTGAACCTCCGTCCATAGTnCTTCAGGCACTCTATCAGATCTAATCCTTTGAATCTATTTGTCACGTCACCTGTATAAT C T 767 AATTGTAAGGGATTTGATTTATCTCATACCTGAATGGCCTAGTGATATATGGAATTAACnGTATGTGTGTTCATGCTTCATTTAACAAACTTATTTAATATATACATGTTCCTGACACT A AGTAT 768 CAATGTCTTATTCTGTGTATCTGTGCCTCGGAGGACATTGTCCAGCACATCCTTTCAAGnGGGTCAACTTGGAGTGGGATCACTGTTTTGTCTCATGTGTAGAAACTTATTCCCTGACA C G 769 AATCTCACAGCTAGAGACACAGCGTCTGTGCCCCACCCCATCTAGTCAGAGAGACAAAGnTCCTGGCCTCGGAGGTTCCCATCAGACAGGGGCACGAGGCCAGTGGACTAGAGACACAC G A 770 AGCAGGCTGAGGAGATAAAGGTTCAAGTCTCAGCTTCTCCACCGACTCTGTGTGACCTGnGGACATCAGTTTCCTCACTTGTAAAATGGGAGAGGGGGGGAAAAAGATGGCCCCCAAGG A G 771 CCGACTCTGTGTGACCTGGGGACATCAGTTTCCTCACTTGTAAAATGGGAGAGGGGGGGnAAAAGATGGCCCCCAAGGTTTTTTTTCCAGCTCTGACTTGGAGTCTGTGCCCATCAGGG G A 772 CGACTCTGTGTGACCTGGGGACATCAGTTTCCTCACTTGTAAAATGGGAGAGGGGGGGAnAAAGATGGCCCCCAAGGTTTTTTTTCCAGCTCTGACTTGGAGTCTGTGCCCATCAGGGG G A 773 GTAATAGGGACCACTCTACACGGTTACGTGGGAAACATCATCGATTTCAACCAGTGCCTnGTGGGGCTTTCCATGCTGCAGCTGCATCTGAAGCTTCTTCTTGGCTCACTCTCATTTAA C T 774 CCAGTGCCTTGTGGGGCTTTCCATGCTGCAGCTGCATCTGAAGCTTCTTCTTGGCTCACnCTCATTTAACATCCCTCTACTTCCCAAGACACAGAATTTGGGATATAGGAACCATCTCA C T 775 CCATCTCATCTGAATGAGGAATGATGCCTCTGTTAGGGATGATCTGATTTTCTCCCTTGnTCTCAGGACTCCCAGTTAGCCCTGGAGCTGGGGATTTGAGTTAAAGGGGTAAGAAGAGC A C 776 GATCTGATTTTCTCCCTTGCTCTCAGGACTCCCAGTTAGCCCTGGAGCTGGGGATTTGAnTTAAAGGGGTAAGAAGAGCTTCTGGTCAGGGCAAGAGTCCTTCCTGAGTAAAAGACACC A G 777 AGCCCTGGAGCTGGGGATTTGAGTTAAAGGGGTAAGAAGAGCTTCTGGTCAGGGCAAGAnTCCTTCCTGAGTAAAAGACACCTCCCAACGGGCCCCAGAAACCTAATGGGTGGGAGAAA A G 778 GAAGATCCTCTGGGGGAAGATCCCCTGGAGAAGGAAACGGCAACCCACTCCAGTACTCTnGCCTGGAAAATCCCATAGATGGAGGAGCCTAGGAGGCTGCAGTCCATGGGGTCACAAAG T C 779 GGAAAATCCCATAGATGGAGGAGCCTAGGAGGCTGCAGTCCATGGGGTCACAAAGAGTCnGACACGACTGAGTGACTTCACTTTGAGCTAAAGGATGAAAATGTCTTTGCCTGAGGGAG A G 780 CTAATCACAAACCTGTGTCCCCATCTGTAGATGGATATTTCACATGGTGGTTGTGAAGCnTAAATGAGATTATGCCTGGAGTGTCTGAGCCTTTGAGTTAGATGACCTGGGTTCGAGGC A G 781 TTCAGACTGTTTTGTTGTCAGCCTGCCCTCAACTCTAAGGAACTCTCTGCTTCTTCAGGnAGATGTCATCCCCAGCATCCTGCTTCAACTCCGGAACGTGAAGAAGGGGAAAGCCAGCC A T 782 TAAGGAACTCTCTGCTTCTTCAGGTAGATGTCATCCCCAGCATCCTGCTTCAACTCCGGnACGTGAAGAAGGGGAAAGCCAGCCAGTTCTTTGGGCTAATGGGGAAGCAGGTAGGAGGT G A 783 CAGGTAGATGTCATCCCCAGCATCCTGCTTCAACTCCGGAACGTGAAGAAGGGGAAAGCnAGCCAGTTCTTTGGGCTAATGGGGAAGCAGGTAGGAGGTGAGTGACAGATGTGGGCGGA A C 784 TTGGGCTAATGGGGAAGCAGGTAGGAGGTGAGTGACAGATGTGGGCGGACACCCAGGGAnAAAGGCTTATGGGTGGGTTCTGTTACCCCAAACAGAGGCCCTAACTTAAAGCCCAGGAC C T 785 TGGGGAAGCAGGTAGGAGGTGAGTGACAGATGTGGGCGGACACCCAGGGATAAAGGCTTnTGGGTGGGTTCTGTTACCCCAAACAGAGGCCCTAACTTAAAGCCCAGGACTCAGCATCC C A 786 TACCCCAAACAGAGGCCCTAACTTAAAGCCCAGGACTCAGCATCCCTTACTCCAGTCCAnTAGTGGTCACTCACGCTATGGAATGGGATACAGTGTCCATATCAATTGTTATCCAAATC A G 787 AAACAGAGGCCCTAACTTAAAGCCCAGGACTCAGCATCCCTTACTCCAGTCCAGTAGTGnTCACTCACGCTATGGAATGGGATACAGTGTCCATATCAATTGTTATCCAAATCAGGACA A G 788 CAGCATCCCTTACTCCAGTCCAGTAGTGGTCACTCACGCTATGGAATGGGATACAGTGTnCATATCAATTGTTATCCAAATCAGGACATTTCAGAGAGTGTTAATTATGCCAGGCAACA T C 789 CACTGTCCATTTGGAGGACATTTTGGCAATATCCATCAAAGTTGGCAACATGCATACCTnCTGACTGATAGGTTCGCTTCAGGAAATCCATCAAATAGAAATGCTATTGCTACATAAGC T TCTGA 790 AAGGTGAATTCTTAACCACTGGACCACCAGGGAAGTCTGGCACATCCATAGCCTTTGTGnCCATTGAAGTGGATGAGGCAGATCTGTGGAAAGATAAAGATTTCCAAGATATTGGCTAA G A 791 CACACATGAAAACATAGGGAGAGTTCCAGGATAAATATCAAACTGTCACCAGTGTTTTAnATCTAGGATAGAAGTGAAGGTGAGGGAGAGCAAAAGTTAAGGGGGACTTTTACTACACT T C 792 GAGGGAGAGCAAAAGTTAAGGGGGACTTTTACTACACTAAACTCTACCTTACCACTTGAnAGTGGGCATTTATTCAGAAACTGCTTTTGTAACTTTAAAAAACACATTTAAAAATAGAG C T 793 CTTTAAAAAACACATTTAAAAATAGAGAAAATCTTCCTGCTACATGCACCATAAAATAAnATAGAGAAAATTAACTTGTGACCAAACTTTGGCCTCAGTTTCTTCCACAAAATGAGTTT A AAT 794 GCACCATAAAATAAAATAGAGAAAATTAACTTGTGACCAAACTTTGGCCTCAGTTTCTTnCACAAAATGAGTTTTGGCCTGGGCCATTTCAGAGATCTCTTTCAAATCCAGAAACCCAG C CCACAA AATGAG TTTTGG 795 CCTTTATCACCAGCAGGGAAACTAAGGTTCACATAGGCTAAGTACTTTCCCAAGGACGCnTGACTAGCACCAGGCAGACTCCACAGTATGCACACTTCCCACTACCCTAAACTGCCTCC T C 796 GGCAGACTCCACAGTATGCACACTTCCCACTACCCTAAACTGCCTCCTACCCAGATGTAnCTGGTGTGGCCCAGTCACACCAGGACAACAGGGGGAGACCAGAGTCCCCAAAGACCCAC C T 797 CCACAGTATGCACACTTCCCACTACCCTAAACTGCCTCCTACCCAGATGTATCTGGTGTnGCCCAGTCACACCAGGACAACAGGGGGAGACCAGAGTCCCCAAAGACCCACCAAAGGCA A G 798 CTAAACTGCCTCCTACCCAGATGTATCTGGTGTGGCCCAGTCACACCAGGACAACAGGGnGAGACCAGAGTCCCCAAAGACCCACCAAAGGCATGGATCCCAAAGAGCCATGAGCTGTT A G 799 AAACTGCCTCCTACCCAGATGTATCTGGTGTGGCCCAGTCACACCAGGACAACAGGGGGnGACCAGAGTCCCCAAAGACCCACCAAAGGCATGGATCCCAAAGAGCCATGAGCTGTTTC T A 800 ATTTCTTCTCTTTCCCCTAGGAATACCTCCCATCCAGTCAGAGGGAACAGGTAAGTGTTnTCCACACCTTCCCCCCACATGCTCCCTGGGGAAGACCGAGTTGTCAGGGAGGTGAGGGA G A 801 GCATAGGCTTCCTGGTTGGTTCCTTGGAGAGGTGGTCTGTGTGCGCCGAGGGAGCAGCTnCAAGGATGAGGAGATGGCGATGAATCCAGTTCTGCCAAAGGTTCAAAATTACCATGGGT C G 802 CAATCCAGAAGGACCTTAAAACTGAAAACCCTAACCCTGTCTTCATGGCCTGGGCATGGnGCCCTCCTTGGCATACTGCCCTGCACTGTTCTGCTGGGTCACATGGCTGGTGTCCTGAG C T 803 AAACTGAAAACCCTAACCCTGTCTTCATGGCCTGGGCATGGTGCCCTCCTTGGCATACTnCCCTGCACTGTTCTGCTGGGTCACATGGCTGGTGTCCTGAGAGTAAAAACCACCCCACG A G 804 ACCTCAGTTCCTAGAGAAATTACTCTATTCCTGAGTCCCCAGTTCTGGTCCTGTCTTTTnTGGTTCCCAAGACAGTCTTCCTCTGCTTCACTTTCTCTTTTTCTTCTCTGTCTCCTCTC T TTGGTT CCCAAG ACAG 805 CAGTTCTGGTCCTGTCTTTTTTGGTTCCCAAGACAGTCTTCCTCTGCTTCACTTTCTCTnTTTCTTCTCTGTCTCCTCTCTTCATCACAAGGGTATCAGCGAGAACCAGTGGTCCAGGG C T 806 GGTATCAGCGAGAACCAGTGGTCCAGGGGCGAGGAGGAGCAACTACAGAAGGTAGGTGAnAGCTTCTCCAGCAGCACACACAGGCACATTCTGCTCCCCACTCTCAGGGCCAGCTGAAG C T 807 GAACCAGTGGTCCAGGGGCGAGGAGGAGCAACTACAGAAGGTAGGTGATAGCTTCTCCAnCAGCACACACAGGCACATTCTGCTCCCCACTCTCAGGGCCAGCTGAAGCCACCGAGAAT C G 808 AGGTAGGTGATAGCTTCTCCAGCAGCACACACAGGCACATTCTGCTCCCCACTCTCAGGnCCAGCTGAAGCCACCGAGAATGCTGTGTGGTTCTCCAGACCCTGGAACACGCCCCTTAT A G 809 CTTCTCCAGCAGCACACACAGGCACATTCTGCTCCCCACTCTCAGGGCCAGCTGAAGCCnCCGAGAATGCTGTGTGGTTCTCCAGACCCTGGAACACGCCCCTTATTCCCTAATTGTTA A ACC 810 TCTTAGGTATTTTCTGTCTTCAACAACCTAAATAAAGGCAATATCACTCTGGGAGGGGTnATCAGCTGACGCTTTCTGGCCTGGGCCACAACCACAAAGGCGTTCAAGGGGATGTTCAA T C 811 TTGAGCCATTTCATTTGAAGGGCCATGGAAGTCACCCCAGTGCCAACATGGAAATGCACnTCCCTCCATTCAAAGCGCTGGCAGGAACCTTAGAAATCATCATTTTTCAGGGATGGAAA G A 812 TCATTTGAAGGGCCATGGAAGTCACCCCAGTGCCAACATGGAAATGCACATCCCTCCATnCAAAGCGCTGGCAGGAACCTTAGAAATCATCATTTTTCAGGGATGGAAACAATTTGCCC G T 813 GTCACACGGTGAACTGTTAACAGAGCCAGGACTAAACACCGTCTCCTGCTCCCTAGTCCnGGCACTTCATGGGACCCTCAGAGGGCCATTGGAATTTTAAGTGCTGGATTACCACTCCC G A 814 AGAGAGGATTAGTGAGGGTTGGCTCATCCACTATCTAGAGGCATTTATGATTGAAAAACnGAAGCTCTGCCAGATTAACCTGGAATTTGATTGCCCTAAATAACTACAGTTGGAGAAAC A G 815 GGCTCCCCTAACCACTGCTTATGTGCAGCACTCTTCCCAGGCAAAGAGGCTGAGAACCAnGGGTCAGAGTGAGAGCCCCCAGCCCCGCCTCCCAGAGGACGAAACCCCTCTCCTTACCT C T 816 AGGACGAAACCCCTCTCCTTACCTGGACGTGGCAGCCAACCAGCCGACCAGGCCAGCCCnCTGCTCCAGGTCTTCTGTGCTCGTGTGTCCCTCCCACCACGCTGAACTCACTGGGCTCC T G 817 AACCCCTCTCCTTACCTGGACGTGGCAGCCAACCAGCCGACCAGGCCAGCCCGCTGCTCnAGGTCTTCTGTGCTCGTGTGTCCCTCCCACCACGCTGAACTCACTGGGCTCCTCCCAGG T C 818 ACCCCTCTCCTTACCTGGACGTGGCAGCCAACCAGCCGACCAGGCCAGCCCGCTGCTCCnGGTCTTCTGTGCTCGTGTGTCCCTCCCACCACGCTGAACTCACTGGGCTCCTCCCAGGA G A 819 CCCCTCTCCTTACCTGGACGTGGCAGCCAACCAGCCGACCAGGCCAGCCCGCTGCTCCAnGTCTTCTGTGCTCGTGTGTCCCTCCCACCACGCTGAACTCACTGGGCTCCTCCCAGGAC T G 820 CCAGGACTCTCGGTCTCAAGCAGCAGTCGTGCACAAGTGTGCTGTTGTCACCTCTGAAAnCTAGTGAATGACCCCACACACTCGGACCTCACTGCATAGCAGGAGTCGTCCCACTGATA G A 821 GTTGTCACCTCTGAAAACTAGTGAATGACCCCACACACTCGGACCTCACTGCATAGCAGnAGTCGTCCCACTGATACCTTCCTACCCCCGTTTCTCTCAATCCTGTGCCCATAACACAG A G 822 CACTGATACCTTCCTACCCCCGTTTCTCTCAATCCTGTGCCCATAACACAGCAAGTGTTnAATAAACCAATGAAGAGCGAATGATTTCTTCTCTGGTGCAGGGCAGCGGACAGGGATGA A C 823 TCAATCCTGTGCCCATAACACAGCAAGTGTTCAATAAACCAATGAAGAGCGAATGATTTnTTCTCTGGTGCAGGGCAGCGGACAGGGATGACCTGGGCTCAACACCCTGCCCAGGGGCC T C 824 CACAGCAAGTGTTCAATAAACCAATGAAGAGCGAATGATTTCTTCTCTGGTGCAGGGCAnCGGACAGGGATGACCTGGGCTCAACACCCTGCCCAGGGGCCTGGCGTGTCAGCAGCCAG C G 825 CTGGTGCAGGGCAGCGGACAGGGATGACCTGGGCTCAACACCCTGCCCAGGGGCCTGGCnTGTCAGCAGCCAGGAGACCTCTTCCAGAGTTGTAAAGGCAAACACTAAATAGCCCCGGT A G 826 ACCCTGCCCAGGGGCCTGGCGTGTCAGCAGCCAGGAGACCTCTTCCAGAGTTGTAAAGGnAAACACTAAATAGCCCCGGTCCTCTGAGGTGGGAAAACGGGCTTGGGACACAGGTAGCC G C 827 GGGGGCCACTGTCCTGGCCCAGCTGTGGTCCTGGGAGGTGGCTCACTGTGACAACCCCAnGTGACGAAGAGAGGGCTGAAGATTTTATTCCCATGTTTGAAGCTGGAGACATTCAAGCT C T 828 AGATTTTATTCCCATGTTTGAAGCTGGAGACATTCAAGCTTCGGCTGAAGCCACTGACCnTTCAGTGAGTTCCCTCCTTGGGCTGGCACTTTGCTGGGCCCTCAGGCGGGACTGGGAGC A C 829 ATTCCCATGTTTGAAGCTGGAGACATTCAAGCTTCGGCTGAAGCCACTGACCCTTCAGTnAGTTCCCTCCTTGGGCTGGCACTTTGCTGGGCCCTCAGGCGGGACTGGGAGCAGGGAGG A G 830 CTTGGGCTGGCACTTTGCTGGGCCCTCAGGCGGGACTGGGAGCAGGGAGGGAGACTGGAnTTTGTCCTTGAAGAACTAAGAACAAAGAGGGCAGAAGCAATGTACTCACTCAAGGCAGC A G 831 GGGCCCTCAGGCGGGACTGGGAGCAGGGAGGGAGACTGGAGTTTGTCCTTGAAGAACTAnAACAAAGAGGGCAGAAGCAATGTACTCACTCAAGGCAGCCCTTGCTCTCCAACAACTCG AG A 832 CCCCGTGCCAATAGAGCTCAGAGGTCCTTGGAGAGGGTTTTCACGAAGGACTCACGTAGnATGCATGGTCCTCATGCTCAGCTTTTGACCTGCAGCCCCACGACAAACTGCTTTCGTTG A G 833 CGTGCCAATAGAGCTCAGAGGTCCTTGGAGAGGGTTTTCACGAAGGACTCACGTAGGATnCATGGTCCTCATGCTCAGCTTTTGACCTGCAGCCCCACGACAAACTGCTTTCGTTGGCT C G 834 TTGACCTGCAGCCCCACGACAAACTGCTTTCGTTGGCTCAGGTCTACAGACGGCACTGCnGCACACCCTGCTGTGGGCCAGAAACCTGGGAGTGACTCCCCAGCCCTCACTGCCCCCTC C T 835 TGGGCCAGAAACCTGGGAGTGACTCCCCAGCCCTCACTGCCCCCTCTAAACACCTCCCCnTAGTTAGTCATTCTTGAAAATATACCTAAATTCTTCTTGCCGCTCTTACTACACTTATT G C 836 CCTCTAAACACCTCCCCCTAGTTAGTCATTCTTGAAAATATACCTAAATTCTTCTTGCCnCTCTTACTACACTTATTCACAGGAGGTACTATCTTCCCTTGCCTAGGGGGCAGCAGCCT A G 837 CCTTCAAGGCCCTGTGCTCCTTGATCCTCACCCCCCATCCCCCCTCAGCCACTACCAGAnATTCTCTCAGACCCTTAGGCACACCAGAGGCTCGCCAGCTTTTGTGATCTGTGCTTAGG T C 838 ACCCTTAGGCACACCAGAGGCTCGCCAGCTTTTGTGATCTGTGCTTAGGCTCTCCCTCTnGGAACGCTGCCCACGCCCCCCTCCCCACCCAACTGGCTAACCCAATCATCTAAGCAAGC C T 839 CAGAGGCTCGCCAGCTTTTGTGATCTGTGCTTAGGCTCTCCCTCTTGGAACGCTGCCCAnGCCCCCCTCCCCACCCAACTGGCTAACCCAATCATCTAAGCAAGCTCCCTTCTCAGTCA T C 840 CCCTCTTGGAACGCTGCCCACGCCCCCCTCCCCACCCAACTGGCTAACCCAATCATCTAnGCAAGCTCCCTTCTCAGTCAGGGCTTCCTGAATAACCAAGCTCAGCTAGTTCTCTCCAG T A 841 CAATCATCTAAGCAAGCTCCCTTCTCAGTCAGGGCTTCCTGAATAACCAAGCTCAGCTAnTTCTCTCCAGTTATGCTTACCCAACACCTGTCCTTTGCCCTTCAGGGCACTGATCACAA C G 842 CAGGGCACTGATCACAATTAGGAATTTAATGCTCATCTTCTCCAGGAGACCAAGTTCTAnATCTTTTGTGTACAAATGAATGACTGAATATATTAGGCACTCTAAAAGACAAGTTACCT C CA 843 GACTGAATATATTAGGCACTCTAAAAGACAAGTTACCTCCACAAGTATTATCGTCAATCnGCACCGGAAATCCCAGAGCCAGGATTTGAGGGAAGGTCCTTCACTCCAAGCACATTTGA A T 844 TACAGACATGTCTCAGGCAGAAAAATAAGGAAGTCTTCACAAGGAATTCCTTTTTAGTTnGGCCATTTCAGTAAGTACCAAAGAAACATCTAAATGTCTGCCCCCACAGCATACTGGTC C G 845 GACTAATCCAGCTGTATGTGGAGGCTGTGTAGGGGAATGATGAAAACTACCCAGGTGGAnTCCACTTATGGAAACTTGAAAGCCAAGATAAATGGGAACTTAATCCAAGAATGGGAAGC G A 846 CAGGTGGAATCCACTTATGGAAACTTGAAAGCCAAGATAAATGGGAACTTAATCCAAGAnTGGGAAGCCACATGAACTCCAGGGGAACTGGAGACCTATTTGTAACAGGATATTCACCT C A 847 CTCCAGGGGAACTGGAGACCTATTTGTAACAGGATATTCACCTTTCCTGATCCACTTCTnTAAGGTGGTGACTAAGAATTCTAAGGCTAGGCAAGGACCTGAGAGGCAACTTGACTGGA G C 848 CATGAATACTGCTCCCCTGGAGCTACACAAGGTGGAGGTCCTCCTCTGGGCACATCTGGnTTCCAATCACAGGCAATCATTCACCAAAATAAAACTACAAGGCCCAACTGTGAAGGCAG T C 849 ATTAATTAACCCAAGTTCAGAAATGACTTCAAAGTCTGTTTCCTAAACCGTATACAAATnTGTGCGTATCTGCATTTATGTACACTTTTCTTTTAAAAAACCCAATACTTTTATTAGAT A G 850 TAACCCAAGTTCAGAAATGACTTCAAAGTCTGTTTCCTAAACCGTATACAAATGTGTGCnTATCTGCATTTATGTACACTTTTCTTTTAAAAAACCCAATACTTTTATTAGATTCTCAA A G 851 TCCTAAACCGTATACAAATGTGTGCGTATCTGCATTTATGTACACTTTTCTTTTAAAAAnCCCAATACTTTTATTAGATTCTCAAAAGGTCAGAAGGAAAGGTCCTTTACTCTCAAGTC T A 852 CTTTTAAAAAACCCAATACTTTTATTAGATTCTCAAAAGGTCAGAAGGAAAGGTCCTTTnCTCTCAAGTCCTTTTTTCACTTACACACTGCTATGTATCTGTATGTATATCTAACCATC T A 853 CCCAAAATAGTCAGTGGTTTAAAGTACTTCCAGGGACTTCCCTGGCAGTCCAATTGTTAnGACTGTGCACATCTACTGTAGGGGTCATGGGTTTGATCCCTAGTCAGGGAACTAAGATC T A 854 CAGGGACTTCCCTGGCAGTCCAATTGTTAAGACTGTGCACATCTACTGTAGGGGTCATGnGTTTGATCCCTAGTCAGGGAACTAAGATCCCATATGCCACTCAGCATGGCCAAAAAAAT A G 855 TCCCTGGCAGTCCAATTGTTAAGACTGTGCACATCTACTGTAGGGGTCATGGGTTTGATnCCTAGTCAGGGAACTAAGATCCCATATGCCACTCAGCATGGCCAAAAAAATAAAACAGT T C 856 TGTGCACATCTACTGTAGGGGTCATGGGTTTGATCCCTAGTCAGGGAACTAAGATCCCAnATGCCACTCAGCATGGCCAAAAAAATAAAACAGTACTTCTCATGATTCTCTAGGGTGGC C T 857 TCCCATATGCCACTCAGCATGGCCAAAAAAATAAAACAGTACTTCTCATGATTCTCTAGnGTGGCAACCCTTAGCTGGAGGATTCTTTAGTTTCAGGAGGTCAGCAGGGTAGAGGGTCT C G 858 TATGCCACTCAGCATGGCCAAAAAAATAAAACAGTACTTCTCATGATTCTCTAGGGTGGnAACCCTTAGCTGGAGGATTCTTTAGTTTCAGGAGGTCAGCAGGGTAGAGGGTCTGGATT C CA 859 TCTCTAGGGTGGCAACCCTTAGCTGGAGGATTCTTTAGTTTCAGGAGGTCAGCAGGGTAnAGGGTCTGGATTTTTGACACTTAAGTTTCTGGTCTGAAAATGTCAGGTTTCCAACTGCA C G 860 GGATTTTTGACACTTAAGTTTCTGGTCTGAAAATGTCAGGTTTCCAACTGCAAAAGTACnAACAGCTAAAATATCACTTCTGGCACCTTTGATTAGTGAGAAGTCCAGCCCACACCCTT G A 861 CACCCTTAAGGAAAATTAGCTCTTATTGGAAGGAGCAGCACTCATATACAGAGATGGGAnTGTTGGTGACCATTTCTGGAGGTGACTTACCACACCTTTTTTTTGAGATAAGGGTATAG C T 862 AGATTTCTAAAAACTCTGCATATGATTGAATAAAACGTCAGTGGTTTCCAAAACATGTAnCGAGTTAAGAAACACTGGTTTTGTGAATGGACATGACTGGTCCAGGGTAAAGATGTTCT C T 863 GGTCCAGGGTAAAGATGTTCTCACACAGAGCATCCAGGGGGAGCAGCGGAGCCAAAGCTnTACGACAACACAGGTTATTTTCTCCACTCGGGCACAAATCAACAAACCCCAAACCCCAG A G 864 TCCAGGGTAAAGATGTTCTCACACAGAGCATCCAGGGGGAGCAGCGGAGCCAAAGCTGTnCGACAACACAGGTTATTTTCTCCACTCGGGCACAAATCAACAAACCCCAAACCCCAGAA G A 865 GGACCTCACTTAATGGGACCTGTCACCTGGGCCTGCACAAACCATGCACAAGCCGAGGGnTGAGTGAAGGCTGGCAGGTGGGGCTCCCGTCTACCTTTTCACTGGAGCTTTCTCAAACC A C 866 AACTGCTCTTCAAAGGAGAAAAAGGCAGACATGTTTATGCCTAGTGACTAATATACTTCnAAAAAAACTGCTTTTCACTCATTTCATATTCCAGAAGGAATGCATGATGGAAGCAAGTT C CA 867 GAATCATCTTGCCATATAAAGGGCACACCATATTCTTAAAAACTACTTAATGTGACTCAnTGTTCCCCCTAGTGAGAAACAGGAAAGCAGGCACCGAGGCATCAGATGACTCACAGTAG T C 868 GGCACACCATATTCTTAAAAACTACTTAATGTGACTCACTGTTCCCCCTAGTGAGAAACnGGAAAGCAGGCACCGAGGCATCAGATGACTCACAGTAGTTTTGTCAGAAGCATGGGATC G A 869 TTCCCCCTAGTGAGAAACAGGAAAGCAGGCACCGAGGCATCAGATGACTCACAGTAGTTnTGTCAGAAGCATGGGATCTGGACTCAAGAGAAGCAACGCTTTCATTCTTTTTCTATAAC C T 870 AGAACCAGAATGAGGCACATCTCTGTATCCTGGTTTAGGTCTCTGACCTACAAATGCTGnCTGCTGCTGCTGCTGCTAAGTCGCTTCAGTCGTGTCCGACTCTGCGTGACCCCATAGTC C CCTG 871 CTACAAATGCTGCCTGCTGCTGCTGCTGCTAAGTCGCTTCAGTCGTGTCCGACTCTGCGnGACCCCATAGTCGGCAGCCCACTAGGCACCCCTGTCCCTGGGATTCTCTAGGCAAGAAC C T 872 CAGTCGTGTCCGACTCTGCGTGACCCCATAGTCGGCAGCCCACTAGGCACCCCTGTCCCnGGGATTCTCTAGGCAAGAACATTGGAGTGGGTTGCCATTTCCTTCTCCAATGCATGAAA T TGGGAT TCTCTA 873 CATTTCCTTCTCCAATGCATGAAAGTGAAAAGGGAAAGTGAAGTCGCTCAGTTGTACCCnACTCTTAGCGACCCCATGGACTGCAGCCTACCAGGCTCCTCCGTCCATGGGATTTTCCA G A 874 CCCCATGGACTGCAGCCTACCAGGCTCCTCCGTCCATGGGATTTTCCAGGCAAGAGTATnGGAGTGGGTCGCCACTGCCTTCTCCAAATGCTGCCTACAGGAGTAACTAAACTCAATTC A T 875 GAAGCAATCAGCACATGCTGAGGCTTTTTTCCTCTAGAAATGGTTGGTGCTTCCACTTAnGGAGTCTCAGAGATGCAGGAATGACTCGAGACTTTTGCTCTTCTAACGAAGGAGCCTAA C T 876 TTCCTCTAGAAATGGTTGGTGCTTCCACTTATGGAGTCTCAGAGATGCAGGAATGACTCnAGACTTTTGCTCTTCTAACGAAGGAGCCTAAGAAGCTAATCTTCTTTTGTACAGGTACA A G 877 TTTAAAGCAGAGAAATCTTCCTTTGATTTCTAGGTGAGGAAAGAGGGATGACAATCACCnAAGACTTGTGATCTGCACTGTCTATCCACTATCATTGAGGTCCACATTACCTTCCTCAA A G 878 GGATGACAATCACCGAAGACTTGTGATCTGCACTGTCTATCCACTATCATTGAGGTCCAnATTACCTTCCTCAATTTTTCCAAAATGGGAGAGACAAGAGAATTTCCCTTTGATGCAAA T C 879 TGTTCCCACTTCCCACAGCTATCCCACCTAGCCTTACCTCCTGCTGGGTCTTCAAATGGnTAACAGAAACTACTCACAGCTACGCATACCTGTTAGCTGGAACCAGAGTGTGACACACA A G 880 AAATGGGTAACAGAAACTACTCACAGCTACGCATACCTGTTAGCTGGAACCAGAGTGTGnCACACAGAATTTACTCCAGCAACTAGACAAGCTCAGAGTTAAGCACTCCCGCCAGATAG G A 881 AGAGTGTGACACACAGAATTTACTCCAGCAACTAGACAAGCTCAGAGTTAAGCACTCCCnCCAGATAGCCTGCATCAGAGGAAAAAACAACTTTCCCCACCCACAAATCATGTCCCTGA T G 882 AAACCTCAAGTGCATTTATTAGTGGTAGGCCAGCGGCACCATTTCACACTCAAATGAGAnTTCCTGGGTGAAACAAATTTCAGCAGAGAACATGCTTTATTGAAGAGTAGATATAGAAC A G 883 CAAAAGCTGCCCCAAGATAGCAGGTTATAATGGGCTAGAGAAATTAGAGGGAGCATCTCnTCCTTCACTTAAACGACACCAAAAATAGAGGAGACCAGAGAATGGGGGGTGGTGGTAAA C T 884 GAAATTAGAGGGAGCATCTCTTCCTTCACTTAAACGACACCAAAAATAGAGGAGACCAGnGAATGGGGGGTGGTGGTAAATCCCAAAAAGGAAATGGAGTTCTTGGAAGGGCATAAGCA G A 885 TTTCATTCCCTTTCACCAAGATGTTGCCCACTGTTCACAGGTGAACTCAAATCCAAATAnAGAATCACCACCTCTCAATTCTTTTCTCCATCTCATTTAGAGCATATGCTGTAACCAAG C G 886 GTAACCAAGACTAATCCCTGCAAGAGTCTTCAGAAGTATTTGGCTCTGGTCAGCCTGATnCTGATTAAAAACAGGTCTTTCAGTAAAAATGGAGGAAATAACTTAAAGTGAGATGAAAT G A 887 CATGGCCCACCCTTGGGCCTGTGGCTCTGGGCAGTGGCCAGTGCGTGACCATAGTATTTnCCCCACAGCATGCTGAATGCAGCTTAGGAGGGAAACAGGCCAGAGCTGCAAATAGGGTG A T 888 ACTACCCTGCAAGCTTTGCGTGGTTAATACCATAGCTACTCTAGTCAATATCTCTAGATnTTTTTCTCAAGTTTTGCTTCTTGGGAGATTTATCAGATTTGTCGAGATTCTACCAATGA T G 889 ATTTCATCTGCGTAGAATCCTACAGTTTATACTCTTTTGTGTCTGGTTTCTTTGGATATnTATTTGAATTTTCAGATTTTCTATTTTGTGCACGTGTCACTTGGTAATTTGTGTCTTTC T A 890 GGCAGCTGCCTGTGGGGCTGGATGCATAGGTGGCCCCAGCATTTGCTGTGCTCCTCTGGnTCCGAGGCCACATATTTCCTGGGGTTCCTCACCCTCGTGTCTGCTCGCTGCTTCCCAGC T C 891 GTGCTCCTCTGGCTCCGAGGCCACATATTTCCTGGGGTTCCTCACCCTCGTGTCTGCTCnCTGCTTCCCAGCAGGGTAGGGAGCTGGTCTGGACCTTGAAAGTGGCACTGCTCCCTTCT T G 892 CTGAGTGATCACCCCACAGAGACCAAGGCAGCACCGCCAGGCAGGCTGCTAGGGCAAACnCAGCCACAGCCACAGGGACAGAAGATTCACCTTGGGAGTGGGCTACACTGCAACTTTGA G A 893 ATCTTTTACTTTTTTTTCCTTGTGTTATTTCCCCTGACTGAACTCTTTATTATGATGTTnATCATAGCTGACTTTCTTCCTGATCCCGGAGAAGAATTTTCAACACTTTACTTTTAAGT G C 894 GTGTTATTTCCCCTGACTGAACTCTTTATTATGATGTTGATCATAGCTGACTTTCTTCCnGATCCCGGAGAAGAATTTTCAACACTTTACTTTTAAGTTTAATTGTTACTTTTTTGTAT T C 895 TATTCCATTTGTTTTGAGACTGTATTATATTGCCTGTTGGAATTGCTTTAATCTGTCTTnTTGATAGGTCTTTTATCATCCAAGGTACAATTTTTCTTGTTGTTGGTATAACGAGTGAT T C 896 AAAACAATCTTCTGTGGCTATAAATACTTTTGAAAGGACAGCTTTAGATGCACTCCTTAnGTTCTGATAAGCCATGCTTTTATGGTAATTCGGCTCAAAGTAATTTCTAATAGCCACTG C T 897 TGAGCCAAGGCCTTTCTCTGATGTTCCCTTTGCCATCTCACCTCCATATGCCCCCTTCAnGCCACATGCCAGGCATGTGCTGGAGGCACTGCTGTGCGGTCAGCGTGGCTCCAAGGCCA T C 898 ACCTGCTTCCCTCGGGGCCTTGGACACCACTGGCTCTTCCTGGGCCCCTGCCCGGCACAnAGGCAGCCACACACATTCTCCTTTTTCCCTTTCTCTTTTCCCCACACCCCACCCCGTTC A G 899 GTACCGCCTGGGCAAGGGGGCTCAGAGCCTGGGTGTTTTTCCCGGGACTACCTCCTGGCnCACAAGCTGAGACCCCAAGCAGCCACTGCTCCTGCCTTTGGCCTCCTTTGATTTCTGCA C T 900 GCTCCTGGAGCTGGGAAACCGGCTGCGAGCGGAGCTGGGGCACCTTACCGGTGGGTCATnCCCCCCACTCCGCCCCTGCTCTGGGGATGGAGGTGCAGGGTGCAGGGCAGGGCTGGCCC TC T 901 AGTGTGCGAGCAGCAACCGAGGGCGTCTTTCACGGGAGCTGGCTCCTTCCCTTGGGACCnGTTTGACAAAGCCCTGCTTTCGTTCAGTCCTCCTTCTGTTCCACAAGTTGAAGGGGAAG T C 902 GTGTGCGAGCAGCAACCGAGGGCGTCTTTCACGGGAGCTGGCTCCTTCCCTTGGGACCTnTTTGACAAAGCCCTGCTTTCGTTCAGTCCTCCTTCTGTTCCACAAGTTGAAGGGGAAGG G A 903 GTCATAGAGTGGGGATCACACAATATGTATTCTCTGATACCTAACATTTCTTAAAGGCTnTTTTTTTTTTTCCCTTGATGTTGAAAATGCTATTTGCTCACTATAAAAATTTCAATGAA C CT 904 AGAGGCAGTACCCTGACAGCTCCTCAGGATGTGCGGTAGGCAATGCAGTTTCCATAGCTnTTTTTTTTTTTCCCTTTAGTTTCTTAGCTTTTGATACAATTCATGTGAAAGATTATTCT G GT 905 CCTTTTTTCTTGAGGTTTCCAGAATATCCTGAGGCTCCTGGACCTGCCAGGAGATGAACnTTCTTATCCCCTCATGAGGCTGGCACCTGGCAGTTTTCCTGGGAGGGCCTTATGAGCCT T A 906 AAGTTGGGAGGAGCTGTTAAAAACAGAGTCCATTGGAACAAATTGGAACTTCAAAGCACnGTGGCTTTTATTGGCTGGGCCATTGCCAGGCAGAGATAAAATCCTTCTCCAGCTGCCAA A G 907 AATGGGTCAGGGGGACAGAGAAGCCTAGGGAGGCAGTGTGCCAGACCAGGAGACACTGGnCTGAGAAACAGAAAGGCTGGCTCTGAGAGGGGCCCAGGAGGCACAGTGTTTTCCACAAC C G 908 CTGTTTTCAGACGTGGGAAAATAGGTAGCAGAGGACCGGGATCCTTGAACGAGGAAGACnAACGAGGCGCCTGTCGGGCCCCCTGGCTTTCTGCCCCGAGGCATCTTCTGGGCTCAGTC A G 909 GCCAGGCCCCTCTGTCCATGAGATTCTCCAGGCAAGAATACTGGAGTGGGTTGCCATTTnCTCCTCCACGGGATCTTTCTGACCGACCCAGGGATCGAACCGAGGTCTCCTGCGTTACA C T 910 TTCTTGTTCCCAAGTTCGTTCTGTTCCTTTCTCTCCAGTTTCTCCCCCTGAAGGCTAGTnCATCTCCTGGTAGATGAGATGTTAGTATTTCCAGATAAGTGTATTGGCAGCCGCTTGAG T C 911 GAGCACCCAGCACCGACAGCCTGTAGCCTCCAGCACCCTGAGGGGAGCCCCACTGTGACnTGGGCAGCCTTTGGCGTTGAAGGGATGAAGATGGAAGCCCAGACAAGGGGCAAGCCTAC G C 912 TTTCTGACCTCCCAAGGGTCTATCAGTGGTCCCAGGAGATAGTAAGGGCCGTGCAGGGCnTGGCCACCAGTCAGTCCTTCCTGGGCTCACGTGATTCCCGATCCGTGTTGTTTTCAGTC C G 913 GGCCTTGGCACTGTTGAGGAGACCAAGCTGTGGTTCTGGCCTGGAGGGCAGCTCGAGATnCTGAGCGCAGAGCCAGCTAGTCAGTGTGGGCACTTCTTCCCACCCCCACATTTGCCCTT A G 914 TGCACACCAGAGGAATCCCAGACATGTCCTGTCACCCCAGTTTCCTCACTCCCCATTGCnTGGCTGATCTTGGAGGCGAGGGCAGGACACCAGGTGCCAGGCAGAGCAGGAGGCAGGAT G A 915 GACCCTTGAGTGTGACAGGGTCCTGGACAGGCACTGCCTGGGGGGAGGGGCGGGGAGGCnGAGGCCTTCCCACTGCCCAGGCCCCAGCCGGAGACCTTGGATGCTGCTCTCCAGGGGCT G A 916 AGACAAAGAGATGGCTGGATGGCATCACTGACTAGATGGACGTGAGTCTGAGTGAACTCnGGGAGTTGGTGATGGACAGGGAGGCCTGGCGTGCTGTGATTCATGGGGTCGCAAAGAGT T C

The column in Table 2 labeled “flanking sequence” provides the sequence information for a reference nucleotide sequence for identification of the polymorphism within the genome of a cattle, such as Norwegian Red cattle. The sequences SEQ ID NO: 1 to 916 are each polymorphic sequences including a polymorphic site (“n”). All or only part of the polymorphic sequence flanking the polymorphic site can be used by the skilled practitioner to identify the polymorphism within the genome of a cattle, such as Norwegian Red cattle. It is to be understood that the information provided in table 2 is a supplement to the information provided in table 1, i.e. P #1 in table 2 and P #1 in table 1 refers to the same polymorphism.

According to particular embodiments, the at least one polymorphism of the invention is selected from the group consisting of P #1 to P #916. According to particular embodiments, the at least one polymorphism of the invention is selected from the group consisting of P #1 to P #310. According to particular embodiments, the at least one polymorphism of the invention is selected from the group consisting of P #13, P #15, P #21-P #32, P #46, P #47, P #54, P #55, P #242-P #247, P #251, P #252, P #261-P #267, P #269, P #311-P #332, P #334-P #343, P #346-P #482, P #595-P #602, P #604-P #608, P #611, P #615, P #616, P #622-P #625, P #627, P #629, P #633-P #667, P #669-P #677, P #679-P #681, P #684-P #687, P #689-P #766, P #768-P #886 (C4:0). According to particular embodiments, the at least one polymorphism of the invention is selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475, P #477-P #481(C16:0). According to particular embodiments, the at least one polymorphism of the invention is selected from the group consisting of P #19, P #34, P #38, P #39, P #141, P #148, P #153, P #233-P #240, P #242-P #246, P #271-P #278, P #280-P #283, P #285, P #289-P #302, P #311-P #334, P #339, P #340, P #343-P #475, P #477-P #481, P #484-P #494, P #497, P #543, P #588, P #589, P #916, P #911, P #14, P #37, P #903, P #7 (C18:1). According to particular embodiments, the at least one polymorphism of the invention is selected from the group consisting of P #1, P #12, P #15-P #17, P #24, P #41, P #63, P #64, P #69-P #71, P #74-P #79, P #83, P #85-P #87, P #89-P #93, P #97-P #103, P #112-P #118, P #120, P #121, P #123-P #135, P #138-P #141, P #148, P #153-P #168, P #218, P #220-P #226, P #249, P #250, P #253-P #260, P #267, P #495, P #499, P #501, P #503-P #514, P #517-P #539, P #541, P #542, P #544-P #547, P #554-P #585, P #590-P #592, P #595-P #597, P #599-P #614, P #617-P #621, P #623-P #652, P #654-P #669, P #672-P #674, P #676-P #678, P #681, P #682, P #688-P #744, P #746-P #769, P #771-P #813, P #815, P #818-P #824, P #826-P #831, P #872 (C6:0). According to particular embodiments, the at least one polymorphism of the invention is selected from the group consisting of P #1, P #10-P #12, P #16-P #19, P #40-P #45, P #48, P #49, P #51, P #56-P #60, P #63-P #66, P #68-P #93, P #97, P #99-P #101, P #103-P #108, P #111-P #118, P #120, P #121, P #123-P #218, P #220, P #224-P #231, P #254, P #258, P #259, P #268, P #270, P #285-P #288, P #302, P #495, P #496, P #498-P #539, P #541-P #551, P #554-P #586, P #590-P #594, P #628, P #682, P #683 (C8:0). According to particular embodiments, the at least one polymorphism of the invention is selected from the group consisting of P #3, P #8-P #10, P #16-P #20, P #49-P #51, P #56-P #62, P #64, P #69-P #72, P #74, P #76-P #78, P #80-P #96, P #104-P #109, P #111-P #115, P #117, P #118, P #120, P #121, P #127, P #128, P #132, P #133, P #136-P #142, P #148-P #153, P #156-P #166, P #224-P #226, P #285-P #288, P #297-P #302, P #490-P #494, P #501-P #514, P #517-P #539, P #541-P #547, P #551, P #554-P #580, P #585, P #586, P #589-P #593, P #628, P #889-P #891, P #899, P #900, P #902-P #916 (C10:0). According to particular embodiments, the at least one polymorphism of the invention is selected from the group consisting of P #3, P #9, P #10, P #16-P #20, P #49-P #53, P #61, P #62, P #64, P #67, P #69-P #72, P #74, P #83, P #85-P #87, P #89-P #96, P #104-P #113, P #115, P #117-P #122, P #127, P #128, P #132, P #133, P #138, P #139, P #141, P #142, P #148-P #151, P #153, P #219, P #224-P #226, P #276, P #285-P #288, P #290-P #302, P #487-P #495, P #497, P #501-P #515, P #517-P #547, P #551, P #554-P #580, P #585, P #586, P #588-P #594, P #887-P #891, P #893-P #916 (C12:0). According to particular embodiments, the at least one polymorphism of the invention is selected from the group consisting of P #9, P #10, P #17-P #19, P #34, P #69, P #70, P #83, P #85, P #117, P #120, P #121, P #127, P #128, P #132, P #133, P #139, P #141, P #148-P #151, P #153, P #224-P #226, P #275, P #276, P #279-P #281, P #284-P #302, P #483-P #494, P #497, P #501-P #514, P #517-P #539, P #541, P #543-P #580, P #584-P #594, P #889-P #892, P #899, P #900, P #902-P #916 (C14:0). According to particular embodiments, the at least one polymorphism of the invention is selected from the group consisting of P #243-P #246, P #314-P #332, P #334-P #340, P #346-P #352, P #354-P #363, P #366-P #392, P #394-P #396, P #398-P #410, P #412-P #475, P #477-P #481(C14:1 cis-9). According to particular embodiments, the at least one polymorphism of the invention is selected from the group consisting of P #4, P #6, P #15 (CLA). According to particular embodiments, the at least one polymorphism of the invention is selected from the group consisting of P #2, P #5 (DHA). According to particular embodiments, the at least one polymorphism of the invention is selected from the group consisting of P #3, P #8-P #10, P #16-P #19, P #44, P #49, P #51, P #56-P #60, P #64-P #66, P #68-P #78, P #83, P #85-P #87, P #89-P #93, P #104-P #108, P #111-P #115, P #117, P #118, P #120, P #121, P #127, P #128, P #132, P #133, P #136-P #153, P #156-P #167, P #170, P #177, P #180, P #181, P #224-P #226, P #231, P #232 (DNS). According to particular embodiments, the at least one polymorphism of the invention is selected from the group consisting of P #34, P #39 (MUFA). According to particular embodiments, the at least one polymorphism of the invention is selected from the group consisting of P #36 (NEFA). According to particular embodiments, the at least one polymorphism of the invention is selected from the group consisting of P #6, P #34, P #35, P #38, P #39 (SAT).

It is understood that the foregoing disclosure regarding the polymorphisms of the invention is applicable to the following aspects.

Method for Selecting a Cattle

The present invention provides in a first aspect a method for selecting a cattle, such as Norwegian Red Cattle, which possesses a genotype which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, the method comprising:

determining the presence of at least one allele, such as at least two, three or four alleles, which in a female milk-producing cattle is indicative of the desired milk fatty acid composition, within the genome of said cattle; and

selecting said cattle when the at least one allele, such as the at least two, three or four alleles, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, is present.

It is to be understood that the term “desired fatty acid composition” as used herein does not necessarily refers to a specific fatty acid composition in milk but rather increase or decrease in the amount of certain fatty acids.

The genotype referred to in the method according to the first aspect of the present invention refers to that part of the genetic make-up of a cattle which determines a specific phenotype, i.e. milk fatty acid composition, only in female milk-producing cattle. Said cattle may be male or female, but the genotype referred to will only determine the specific phenotype in female milk-producing cattle.

A female milk-producing cattle selected by the method according to the first aspect of the present invention will have a desired milk fatty acid composition. A male cattle selected by the method according to the first aspect of the present invention possesses a genotype which in a female milk-producing cattle is indicative of a desired milk fatty acid composition and may therefore find use as a breeding animal or as a producer of semen or sperm which may find use in various breeding programs.

Since the genotype referred to in the above method determines a specific phenotype only in female milk-producing cattle, it has been decided to differentiate between a female cattle, which not necessarily produces milk, and a female milk-producing cattle, which produces milk by definition.

The cattle referred to in the above method may be male or female. In one embodiment according to the present invention, said cattle is male. In another embodiment according to the present invention, said cattle is female, preferably a female milk-producing cattle.

In one embodiment according to the present invention, said cattle is Norwegian Red cattle.

In one embodiment according to the present invention, said female milk-producing cattle is female milk-producing Norwegian Red cattle.

A female milk-producing individual having a desired milk fatty acid composition has a higher probability of a desired milk fatty acid composition than a random female individual (under the same conditions) with whom it is comparable. Two female individuals are comparable if they are, with regards to all discriminating factors except the genotype at the polymorphic site which is used for predicting milk fatty acid composition, random representatives of one and the same population of female cattle.

In one embodiment according to the first aspect of the present invention, the at least one allele is an allele of at least one polymorphism, such as at least one single nucleotide polymorphism (SNP). In a preferred embodiment, the at least one polymorphism is selected from the polymorphisms listed in table 1.

The polymorphism of the present invention can be present in either of two forms, i.e., the polymorphisms have a total of two alleles. The at least one allele referred to above is herein meant to refer to one of the two alternative forms of the polymorphism, i.e. one of the two alternatives that is present at the polymorphic site. Said in other words, P #15 has a total of two polymorphism alleles (A/G), i.e. there may be an adenine at the polymorphic site or a guanine at the polymorphic site. An adenine at the polymorphic represents one polymorphism allele while a guanine at the polymorphic site represents the other polymorphism allele. A polymorphism allele referred to as a “fat allele” for a specific trait is indicative of increased amount of that trait in milk while a polymorphism allele referred to as a “non-fat allele” for a specific trait is indicative of decreased amount of that trait in milk.

The knowledge provided in table 1 makes it possible to select a cattle possessing a genotype which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. If it e.g. is desirable to reduce the amount of C16:0 in milk in order to provide milk with a healthier fatty acid profile, the at least one allele referred to above should preferably represent a “non-fat allele” for C16:0. One example of such an allele is P #33 where an adenine is positioned at the polymorphic site.

In another embodiment according to the first aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #1 to P #916, such as P #1 to P #310. In another embodiment according to the first aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481 (C16:0), preferably the at least one allele represents a “non-fat allele” for C16:0. In another embodiment according to the first aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #19, P #34, P #38, P #39, P #141, P #148, P #153, P #233-P #240, P #242-P #246, P #271-P #278, P #280-P #283, P #285, P #289-P #302, P #311-P #334, P #339, P #340, P #343-P #475, P #477-P #481, P #484-P #494, P #497, P #543, P #588, P #589, P #916, P #911, P #14, P #37, P #903 and P #7 (C18:1), preferably the at least one allele represents a “fat allele” for C18:1. In another embodiment according to the first aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #1, P #12, P #15-P #17, P #24, P #41, P #63, P #64, P #69-P #71, P #74-P #79, P #83, P #85-P #87, P #89-P #93, P #97-P #103, P #112-P #118, P #120, P #121, P #123-P #135, P #138-P #141, P #148, P #153-P #168, P #218, P #220-P #226, P #249, P #250, P #253-P #260, P #267, P #495, P #499, P #501, P #503-P #514, P #517-P #539, P #541, P #542, P #544-P #547, P #554-P #585, P #590-P #592, P #595-P #597, P #599-P #614, P #617-P #621, P #623-P #652, P #654-P #669, P #672-P #674, P #676-P #678, P #681, P #682, P #688-P #744, P #746-P #769, P #771-P #813, P #815, P #818-P #824, P #826-P #831 and P #872 (C6:0), preferably the at least one allele represents a “fat allele” for C6:0. In another embodiment according to the first aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #1, P #10-P #12, P #16-P #19, P #40-P #45, P #48, P #49, P #51, P #56-P #60, P #63-P #66, P #68-P #93, P #97, P #99-P #101, P #103-P #108, P #111-P #118, P #120, P #121, P #123-P #218, P #220, P #224-P #231, P #254, P #258, P #259, P #268, P #270, P #285-P #288, P #302, P #495, P #496, P #498-P #539, P #541-P #551, P #554-P #586, P #590-P #594, P #628, P #682 and P #683 (C8:0), preferably the at least one allele represents a “fat allele” for C8:0. In another embodiment according to the first aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #3, P #8-P #10, P #16-P #20, P #49-P #51, P #56-P #62, P #64, P #69-P #72, P #74, P #76-P #78, P #80-P #96, P #104-P #109, P #111-P #115, P #117, P #118, P #120, P #121, P #127, P #128, P #132, P #133, P #136-P #142, P #148-P #153, P #156-P #166, P #224-P #226, P #285-P #288, P #297-P #302, P #490-P #494, P #501-P #514, P #517-P #539, P #541-P #547, P #551, P #554-P #580, P #585, P #586, P #589-P #593, P #628, P #889-P #891, P #899, P #900, P #902-P #916 (C10:0), preferably the at least one allele represents a “fat allele” for C10:0. In another embodiment according to the first aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #3, P #9, P #10, P #16-P #20, P #49-P #53, P #61, P #62, P #64, P #67, P #69-P #72, P #74, P #83, P #85-P #87, P #89-P #96, P #104-P #113, P #115, P #117-P #122, P #127, P #128, P #132, P #133, P #138, P #139, P #141, P #142, P #148-P #151, P #153, P #219, P #224-P #226, P #276, P #285-P #288, P #290-P #302, P #487-P #495, P #497, P #501-P #515, P #517-P #547, P #551, P #554-P #580, P #585, P #586, P #588-P #594, P #887-P #891, P #893-P #916 (C12:0), preferably the at least one allele represents a “fat allele” for C12:0. In another embodiment according to the first aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #9, P #10, P #17-P #19, P #34, P #69, P #70, P #83, P #85, P #117, P #120, P #121, P #127, P #128, P #132, P #133, P #139, P #141, P #148-P #151, P #153, P #224-P #226, P #275, P #276, P #279-P #281, P #284-P #302, P #483-P #494, P #497, P #501-P #514, P #517-P #539, P #541, P #543-P #580, P #584-P #594, P #889-P #892, P #899, P #900, P #902-P #916 (C14:0), preferably the at least one allele represents a “fat allele” for C14:0. In another embodiment according to the first aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #243-P #246, P #314-P #332, P #334-P #340, P #346-P #352, P #354-P #363, P #366-P #392, P #394-P #396, P #398-P #410, P #412-P #475 and P #477-P #481 (C14:1 cis-9), preferably the at least one allele represents a “fat allele” for C14:1 cis-9.

In another embodiment according to the first aspect of the present invention, a desired milk fatty acid composition is decreased amount of C16:0 in milk; and/or increased amount of C18:1 in milk; and/or increased amount of C14:1 cis-9 in milk; and/or increased amount of one or more fatty acids selected from the group consisting of C6:0, C8:0, C10:0, C12:0 and C14:0 in milk; and/or optionally any combination thereof.

A female individual having decreased amount of one or more fatty acids in the milk has a higher probability of decreased amount of the one or more fatty acids in the milk than a random female individual (under the same conditions) with whom it is comparable. Two female individuals are comparable if they are, with regards to all discriminating factors except the genotype at the polymorphic site which is used for predicting decreased amount of one or more fatty acids in the milk, random representatives of one and the same population of cattle.

A female individual having increased amount of one or more fatty acids in the milk has a higher probability of increased amount of the one or more fatty acids in the milk than a random female individual (under the same conditions) with whom it is comparable. Two female individuals are comparable if they are, with regards to all discriminating factors except the genotype at the polymorphic site which is used for predicting increased amount of one or more fatty acids in the milk, random representatives of one and the same population of cattle.

Nearly all mammals, including non-human mammals such as cattle and in particular Norwegian Red cattle, are diploid organisms and thus possess at least one copy of the polymorphisms of the invention. In a preferred embodiment, the selected cattle is homozygote with respect to the at least one allele. In another embodiment according to the present invention, the selected cattle is heterozygote with respect to the at least one allele.

The at least one allele, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, may affect the fatty acid composition in female milk-producing cattle through a number of different mechanisms. The milk fatty acid composition may e.g. be the result of:

-   -   a change in a regulatory sequence of a gene which e.g. may         affect the level of transcription and/or translation; and/or     -   a change in amino acid sequence of a protein which e.g. may         affect the activity of an enzyme.

Since the at least one allele, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, may affect the fatty acid composition in female milk-producing cattle through a number of different mechanisms, it is to be understood that presence of the at least one allele may be determined e.g. by a) identifying a change in DNA sequence, b) identifying a change in RNA sequence, such as mRNA sequence, c) identifying a change in protein sequence, d) identifying a change in transcription level, e) identifying a change in expression level and/or f) identifying a change in protein activity, such as enzymatic activity in case the protein in question is an enzyme.

Numerous techniques are known in the art for a) identifying a change in a DNA sequence, b) identifying a change in a RNA sequence, such as a mRNA sequence, c) identifying a change in protein sequence, d) identifying a change in transcription level, e) identifying a change in expression level, and/or f) identifying a change in protein activity, and a person skilled in the art will easily know how to identify such changes.

According to other particular embodiments, the at least one allele is a “fat allele” or a “non-fat allele”, preferably the latter, for C16:0 of at least one polymorphism selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C18:1 of at least one polymorphism selected from the group consisting of P #19, P #34, P #38, P #39, P #141, P #148, P #153, P #233-P #240, P #242-P #246, P #271-P #278, P #280-P #283, P #285, P #289-P #302, P #311-P #334, P #339, P #340, P #343-P #475, P #477-P #481, P #484-P #494, P #497, P #543, P #588, P #589, P #916, P #911, P #14, P #37, P #903 and P #7.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C6:0 of at least one polymorphism selected from the group consisting of P #1, P #12, P #15-P #17, P #24, P #41, P #63, P #64, P #69-P #71, P #74-P #79, P #83, P #85-P #87, P #89-P #93, P #97-P #103, P #112-P #118, P #120, P #121, P #123-P #135, P #138-P #141, P #148, P #153-P #168, P #218, P #220-P #226, P #249, P #250, P #253-P #260, P #267, P #495, P #499, P #501, P #503-P #514, P #517-P #539, P #541, P #542, P #544-P #547, P #554-P #585, P #590-P #592, P #595-P #597, P #599-P #614, P #617-P #621, P #623-P #652, P #654-P #669, P #672-P #674, P #676-P #678, P #681, P #682, P #688-P #744, P #746-P #769, P #771-P #813, P #815, P #818-P #824, P #826-P #831 and P #872.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C8:0 of at least one polymorphism selected from the group consisting of P #1, P #10-P #12, P #16-P #19, P #40-P #45, P #48, P #49, P #51, P #56-P #60, P #63-P #66, P #68-P #93, P #97, P #99-P #101, P #103-P #108, P #111-P #118, P #120, P #121, P #123-P #218, P #220, P #224-P #231, P #254, P #258, P #259, P #268, P #270, P #285-P #288, P #302, P #495, P #496, P #498-P #539, P #541-P #551, P #554-P #586, P #590-P #594, P #628, P #682 and P #683.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C10:0 of at least one polymorphism selected from the group consisting of P #3, P #8-P #10, P #16-P #20, P #49-P #51, P #56-P #62, P #64, P #69-P #72, P #74, P #76-P #78, P #80-P #96, P #104-P #109, P #111-P #115, P #117, P #118, P #120, P #121, P #127, P #128, P #132, P #133, P #136-P #142, P #148-P #153, P #156-P #166, P #224-P #226, P #285-P #288, P #297-P #302, P #490-P #494, P #501-P #514, P #517-P #539, P #541-P #547, P #551, P #554-P #580, P #585, P #586, P #589-P #593, P #628, P #889-P #891, P #899, P #900, P #902-P #916.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C12:0 of at least one polymorphism selected from the group consisting of P #3, P #9, P #10, P #16-P #20, P #49-P #53, P #61, P #62, P #64, P #67, P #69-P #72, P #74, P #83, P #85-P #87, P #89-P #96, P #104-P #113, P #115, P #117-P #122, P #127, P #128, P #132, P #133, P #138, P #139, P #141, P #142, P #148-P #151, P #153, P #219, P #224-P #226, P #276, P #285-P #288, P #290-P #302, P #487-P #495, P #497, P #501-P #515, P #517-P #547, P #551, P #554-P #580, P #585, P #586, P #588-P #594, P #887-P #891, P #893-P #916.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C14:0 of at least one polymorphism selected from the group consisting of P #9, P #10, P #17-P #19, P #34, P #69, P #70, P #83, P #85, P #117, P #120, P #121, P #127, P #128, P #132, P #133, P #139, P #141, P #148-P #151, P #153, P #224-P #226, P #275, P #276, P #279-P #281, P #284-P #302, P #483-P #494, P #497, P #501-P #514, P #517-P #539, P #541, P #543-P #580, P #584-P #594, P #889-P #892, P #899, P #900, P #902-P #916.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C14:1 cis-9 of at least one polymorphism selected from the group consisting of P #243-P #246, P #314-P #332, P #334-P #340, P #346-P #352, P #354-P #363, P #366-P #392, P #394-P #396, P #398-P #410, P #412-P #475 and P #477-P #481.

It is to be understood that a “fat-allele” for a specific trait is indicative of increased amount of that trait in milk; and a “non-fat allele” for a specific trait is indicative of decreased amount of that trait in milk (“fat allele”, “non-fat allele” and the respective traits are specified in table 1).

According to other particular embodiments, the present invention provides a method for selecting a cattle which possesses a genotype which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, the method comprising:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NOs: 1 to 916, such as SEQ ID NOs: 1 to 310; or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NOs: 1 to 916, such as SEQ ID NOs: 1 to 310, by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions); and

selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition.

In one embodiment according to the present invention, the nucleotide substitution(s) and/or nucleotide deletions (preferably substitutions) are not in the polymorphic site (i.e. position 60) of the derived sequence.

If e.g. the polymorphism is located within the genome of the cattle at a position corresponding to position 60 of the nucleotide sequence set forth in SEQ ID NOs: 1, the “respective polymorphism” referred to above is P #1. If e.g. the polymorphism is located within the genome of the cattle at a position corresponding to position 60 of the nucleotide sequence set forth in SEQ ID NOs: 10, the “respective polymorphism” referred to above is P #10. Similarly, if e.g. the polymorphism is located within the genome of the cattle at a position corresponding to position 60 of a nucleotide sequence which is derived from the nucleotide sequence set forth in SEQ ID NOs: 1 by 1 to 5 nucleotide substitutions, the “respective polymorphism” referred to above is still P #1. Similarly, if e.g. the polymorphism is located within the genome of the cattle at a position corresponding to position 60 of a nucleotide sequence which is derived from the nucleotide sequence set forth in SEQ ID NOs: 10 by 1 to 5 nucleotide substitutions, the “respective polymorphism” referred to above is still P #10.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQIDNOs 33, 241-248, 303-312, 314-344, 346-475 and, 477-481 (C16:0); or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of 33, 241-248, 303-312, 314-344, 346-475 and, 477-481 (C16:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions); and

selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotide corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, a desired milk fatty acid composition is decreased content of C16:0 in milk and the at least one allele is a “non-fat allele” for C16:0.

In one embodiment according to the present invention, the nucleotide substitution(s) and/or nucleotide deletions (preferably substitutions) are not in the polymorphic site (i.e. position 60) of the derived sequence.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NOs: 19, 34, 38, 39, 141, 148, 153, 233-240, 242-246, 271-278, 280-283, 285, 289-302, 311-334, 339, 340, 343-475, 477-481, 484-494, 497, 543, 588, 589, 916, 911, 14, 37, 903 and 7 (C18:1); or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NOs: 19, 34, 38, 39, 141, 148, 153, 233-240, 242-246, 271-278, 280-283, 285, 289-302, 311-334, 339, 340, 343-475, 477-481, 484-494, 497, 543, 588, 589, 916, 911, 14, 37, 903 and 7 (C18:1) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions); and

selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, a desired milk fatty acid composition is increased content of C18:1 in milk and the at least one allele is a “fat allele” for C18:1.

In one embodiment according to the present invention, the nucleotide substitution(s) and/or nucleotide deletions (preferably substitutions) are not in the polymorphic site (i.e. position 60) of the derived sequence.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NOs: 243-246, 314-332, 334-340, 346-352, 354-363, 366-392, 394-396, 398-410, 412-475 and 477-481 (C14:1 cis-9); or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NOs: 243-246, 314-332, 334-340, 346-352, 354-363, 366-392, 394-396, 398-410, 412-475 and 477-481 (C14:1 cis-9) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions); and

selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, a desired milk fatty acid composition is increased content of C14:1 cis-9 in milk and the at least one allele is a “fat allele” for C14:1 cis-9.

In one embodiment according to the present invention, the nucleotide substitution(s) and/or nucleotide deletions (preferably substitutions) are not in the polymorphic site (i.e. position 60) of the derived sequence.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NOs: 1, 12, 15-17, 24, 41, 63, 64, 69-71, 74-79, 83, 85-87, 89-93, 97-103, 112-118, 120, 121, 123-135, 138-141, 148, 153-168, 218, 220-226, 249, 250, 253-260, 267, 495, 499, 501, 503-514, 517-539, 541, 542, 544-547, 554-585, 590-592, 595-597, 599-614, 617-621, 623-652, 654-669, 672-674, 676-678, 681, 682, 688-744, 746-769, 771-813, 815, 818-824, 826-831 and 872 (C6:0); or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NOs: 1, 12, 15-17, 24, 41, 63, 64, 69-71, 74-79, 83, 85-87, 89-93, 97-103, 112-118, 120, 121, 123-135, 138-141, 148, 153-168, 218, 220-226, 249, 250, 253-260, 267, 495, 499, 501, 503-514, 517-539, 541, 542, 544-547, 554-585, 590-592, 595-597, 599-614, 617-621, 623-652, 654-669, 672-674, 676-678, 681, 682, 688-744, 746-769, 771-813, 815, 818-824, 826-831 and 872 (C6:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions); and

selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, a desired milk fatty acid composition is increased content of C6:0 in milk and the at least one allele is a “fat allele” for C6:0.

In one embodiment according to the present invention, the nucleotide substitution(s) and/or nucleotide deletions (preferably substitutions) are not in the polymorphic site (i.e. position 60) of the derived sequence.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NOs: 1, 10-12, 16-19, 40-45, 48, 49, 51, 56-60, 63-66, 68-93, 97, 99-101, 103-108, 111-118, 120, 121, 123-218, 220, 224-231, 254, 258, 259, 268, 270, 285-288, 302, 495, 496, 498-539, 541-551, 554-586, 590-594, 628, 682 and 683 (C8:0); or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NOs: 1, 10-12, 16-19, 40-45, 48, 49, 51, 56-60, 63-66, 68-93, 97, 99-101, 103-108, 111-118, 120, 121, 123-218, 220, 224-231, 254, 258, 259, 268, 270, 285-288, 302, 495, 496, 498-539, 541-551, 554-586, 590-594, 628, 682 and 683 (C8:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions); and

selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, a desired milk fatty acid composition is increased content of C8:0 in milk and the at least one allele is a “fat allele” for C8:0.

In one embodiment according to the present invention, the nucleotide substitution(s) and/or nucleotide deletions (preferably substitutions) are not in the polymorphic site (i.e. position 60) of the derived sequence.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NOs: 3, 8-10, 16-20, 49-51, 56-62, 64, 69-72, 74, 76-78, 80-96, 104-109, 111-115, 117, 118, 120, 121, 127, 128, 132, 133, 136-142, 148-153, 156-166, 224-226, 285-288, 297-302, 490-494, 501-514, 517-539, 541-547, 551, 554-580, 585, 586, 589-593, 628, 889-891, 899, 900, 902-916 (C10:0); or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NOs: 3, 8-10, 16-20, 49-51, 56-62, 64, 69-72, 74, 76-78, 80-96, 104-109, 111-115, 117, 118, 120, 121, 127, 128, 132, 133, 136-142, 148-153, 156-166, 224-226, 285-288, 297-302, 490-494, 501-514, 517-539, 541-547, 551, 554-580, 585, 586, 589-593, 628, 889-891, 899, 900, 902-916 (C10:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions); and

selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, a desired milk fatty acid composition is increased content of C10:0 in milk and the at least one allele is a “fat allele” for C10:0.

In one embodiment according to the present invention, the nucleotide substitution(s) and/or nucleotide deletions (preferably substitutions) are not in the polymorphic site (i.e. position 60) of the derived sequence.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NOs: 3, 9, 10, 16-20, 49-53, 61, 62, 64, 67, 69-72, 74, 83, 85-87, 89-96, 104-113, 115, 117-122, 127, 128, 132, 133, 138, 139, 141, 142, 148-151, 153, 219, 224-226, 276, 285-288, 290-302, 487-495, 497, 501-515, 517-547, 551, 554-580, 585, 586, 588-594, 887-891, 893-916 (C12:0); or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NOs: 3, 9, 10, 16-20, 49-53, 61, 62, 64, 67, 69-72, 74, 83, 85-87, 89-96, 104-113, 115, 117-122, 127, 128, 132, 133, 138, 139, 141, 142, 148-151, 153, 219, 224-226, 276, 285-288, 290-302, 487-495, 497, 501-515, 517-547, 551, 554-580, 585, 586, 588-594, 887-891, 893-916 (C12:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions); and

selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, a desired milk fatty acid composition is increased content of C12:0 in milk and the at least one allele is a “fat allele” for C12:0.

In one embodiment according to the present invention, the nucleotide substitution(s) and/or nucleotide deletions (preferably substitutions) are not in the polymorphic site (i.e. position 60) of the derived sequence.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NOs: 9, 10, 17-19, 34, 69, 70, 83, 85, 117, 120, 121, 127, 128, 132, 133, 139, 141, 148-151, 153, 224-226, 275, 276, 279-281, 284-302, 483-494, 497, 501-514, 517-539, 541, 543-580, 584-594, 889-892, 899, 900, 902-916 (C14:0); or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NOs: 9, 10, 17-19, 34, 69, 70, 83, 85, 117, 120, 121, 127, 128, 132, 133, 139, 141, 148-151, 153, 224-226, 275, 276, 279-281, 284-302, 483-494, 497, 501-514, 517-539, 541, 543-580, 584-594, 889-892, 899, 900, 902-916 (C14:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions); and

selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, a desired milk fatty acid composition is increased content of C14:0 in milk and the at least one allele is a “fat allele” for C14:0.

In one embodiment according to the present invention, the nucleotide substitution(s) and/or nucleotide deletions (preferably substitutions) are not in the polymorphic site (i.e. position 60) of the derived sequence.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being selected from the group consisting of P #1 to P #916; and

selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the allele, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, of the respective polymorphisms listed in table 1.

If e.g. the at least one polymorphism is P #1, the respective polymorphism listed in table 1 is P #1. Similarly, if e.g. the at least one polymorphism is P #10, the respective polymorphism listed in table 1 is P #10.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481 (C16:0); and

selecting said cattle when the one or more nucleotides of the at least one allele is a nucleotide corresponding to the “non-fat allele” for C16:0 of the respective polymorphisms listed in table 1.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being selected from the group consisting of P #19, P #34, P #38, P #39, P #141, P #148, P #153, P #233-P #240, P #242-P #246, P #271-P #278, P #280-P #283, P #285, P #289-P #302, P #311-P #334, P #339, P #340, P #343-P #475, P #477-P #481, P #484-P #494, P #497, P #543, P #588, P #589, P #916, P #911, P #14, P #37, P #903 and P #7 (C18:1); and selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the “fat allele” for C18:1 of the respective polymorphisms listed in table 1.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being selected from the group consisting of P #243-P #246, P #314-P #332, P #334-P #340, P #346-P #352, P #354-P #363, P #366-P #392, P #394-P #396, P #398-P #410, P #412-P #475 and P #477-P #481 (C14:1 cis-9); and

selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the “fat allele” for C14:1 cis-9 of the respective polymorphisms listed in table 1.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being selected from the group consisting of P #1, P #12, P #15-P #17, P #24, P #41, P #63, P #64, P #69-P #71, P #74-P #79, P #83, P #85-P #87, P #89-P #93, P #97-P #103, P #112-P #118, P #120, P #121, P #123-P #135, P #138-P #141, P #148, P #153-P #168, P #218, P #220-P #226, P #249, P #250, P #253-P #260, P #267, P #495, P #499, P #501, P #503-P #514, P #517-P #539, P #541, P #542, P #544-P #547, P #554-P #585, P #590-P #592, P #595-P #597, P #599-P #614, P #617-P #621, P #623-P #652, P #654-P #669, P #672-P #674, P #676-P #678, P #681, P #682, P #688-P #744, P #746-P #769, P #771-P #813, P #815, P #818-P #824, P #826-P #831 and P #872 (C6:0); and

selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the “fat allele” for C6:0 of the respective polymorphisms listed in table 1.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being selected from the group consisting of P #1, P #10-P #12, P #16-P #19, P #40-P #45, P #48, P #49, P #51, P #56-P #60, P #63-P #66, P #68-P #93, P #97, P #99-P #101, P #103-P #108, P #111-P #118, P #120, P #121, P #123-P #218, P #220, P #224-P #231, P #254, P #258, P #259, P #268, P #270, P #285-P #288, P #302, P #495, P #496, P #498-P #539, P #541-P #551, P #554-P #586, P #590-P #594, P #628, P #682 and P #683 (C8:0); and

selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the “fat allele” for C8:0 of the respective polymorphisms listed in table 1.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being selected from the group consisting of P #3, P #8-P #10, P #16-P #20, P #49-P #51, P #56-P #62, P #64, P #69-P #72, P #74, P #76-P #78, P #80-P #96, P #104-P #109, P #111-P #115, P #117, P #118, P #120, P #121, P #127, P #128, P #132, P #133, P #136-P #142, P #148-P #153, P #156-P #166, P #224-P #226, P #285-P #288, P #297-P #302, P #490-P #494, P #501-P #514, P #517-P #539, P #541-P #547, P #551, P #554-P #580, P #585, P #586, P #589-P #593, P #628, P #889-P #891, P #899, P #900, P #902-P #916 (C10:0); and

selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the “fat allele” for C10:0 of the respective polymorphisms listed in table 1.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being selected from the group consisting of P #3, P #9, P #10, P #16-P #20, P #49-P #53, P #61, P #62, P #64, P #67, P #69-P #72, P #74, P #83, P #85-P #87, P #89-P #96, P #104-P #113, P #115, P #117-P #122, P #127, P #128, P #132, P #133, P #138, P #139, P #141, P #142, P #148-P #151, P #153, P #219, P #224-P #226, P #276, P #285-P #288, P #290-P #302, P #487-P #495, P #497, P #501-P #515, P #517-P #547, P #551, P #554-P #580, P #585, P #586, P #588-P #594, P #887-P #891, P #893-P #916 (C12:0); and

selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the “fat allele” for C12:0 of the respective polymorphisms listed in table 1.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being selected from the group consisting of P #9, P #10, P #17-P #19, P #34, P #69, P #70, P #83, P #85, P #117, P #120, P #121, P #127, P #128, P #132, P #133, P #139, P #141, P #148-P #151, P #153, P #224-P #226, P #275, P #276, P #279-P #281, P #284-P #302, P #483-P #494, P #497, P #501-P #514, P #517-P #539, P #541, P #543-P #580, P #584-P #594, P #889-P #892, P #899, P #900, P #902-P #916 (C14:0); and

selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the “fat allele” for C14:0 of the respective polymorphisms listed in table 1.

Numerous techniques are known in the art for determining the identity of one or more nucleotides of an allele present at a polymorphic site. For example, the determination may involve sequence analysis of the cattle to be tested using, e.g., traditional sequence methodologies (e.g., the “dideoxy-mediated chain termination method,” also known as the “Sanger Method” (Sanger, F., et al., J. Molec. Biol. 94: 441 (1975); Prober et al. Science 238: 336-340 (1987)) and the “chemical degradation method” also known as the “Maxam-Gilbert method” (Maxam, A. M., et al., Proc. Natl. Acad. Sci. (U.S.A) 74: 560 (1977). Alternatively, the determination may involve single base extension of DNA oligonucleotides terminating at the polymorphic site (e.g. iPLEX assays from Sequenom (San Diego, USA) and Infinium assays from Illumina (San Diego, USA), allele-specific ligation assays (e.g. Axiom technology from Affymetrix (San Diego, USA), allele-specific PCR (e.g. SNPtype assays from Fluidigm (San Francisco) or KASP assays from LGC Genomics (Teddington, UK)), or competitive hybridisation of probes complementary to the different alleles (e.g. the TaqMan assay from Applied Biosystems (Foster City, USA)).

Methods for the detection of allelic variation are also reviewed by Nollau et al., Clin. Chem. 43, 1114-1120, 1997; and in standard textbooks, for example “Laboratory Protocols for Mutation Detection”, Ed. by U. Landegren, Oxford University Press, 1996 and “PCR”, 2nd Edition by Newton & Graham, BIOS Scientific Publishers Limited, 1997.

For analyzing SNPs, it may for example be appropriate to use oligonucleotides specific for alternative SNP alleles. Such oligonucleotides which detect single nucleotide variations in target sequences may be referred to by such terms as “allele-specific oligonucleotides”, “allele-specific probes”, or “allele-specific primers”. The design and use of allele-specific probes for analyzing polymorphisms is described in, e.g., Mutation Detection A Practical Approach, ed. Cotton et al. Oxford University Press, 1998; Saiki et al., Nature 324, 163-166 (1986); Dattagupta, EP235726; and Saiki, WO 89/11548.

Non-Human Gamete

The present invention provides in a second aspect a non-human gamete, such as an isolated non-human gamete, comprising within its genome at least one allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition.

As used herein, “isolated” means that an organism or a biological component, such as a cell, population of cells or a nucleic acid molecule, has been separated from its natural environment.

The at least one allele referred to in the second aspect of the present invention refers to an allele which determines a specific phenotype (milk fatty acid composition) only in female milk-producing cattle. A non-human gamete which comprises within its genome at least one allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition may find use in various breeding programs.

Since the at least one allele referred to in the second aspect of the present invention determines a specific phenotype only in female milk-producing cattle, it has been decided to differentiate between a female cattle, which not necessarily produces milk, and a female milk-producing cattle, which produces milk by definition.

According to particular embodiments, the non-human gamete is a non-human semen. In particular embodiments the non-human semen has been isolated from a male cattle, in particular from a male cattle selected by the method according to the first aspect of the present invention.

Semen, also known as seminal fluid, is an organic fluid that may contain spermatozoa. It is secreted by the gonads (sexual glands) and other sexual organs of male or hermaphroditic animals and can fertilize female ova. In one embodiment according to the present invention said non-human semen comprises at least one spermatozoa.

According to particular embodiments, the non-human gamete is a non-human spermatozoa. In particular embodiments, the non-human spermatozoa has been isolated from a male cattle, in particular from a male cattle selected by the method according to the first aspect of the present invention.

A spermatozoon is a motile sperm cell, or moving form of the haploid cell that is the male gamete. A spermatozoon joins an ovum to form a zygote. A zygote is a single cell, with a complete set of chromosomes, that normally develops into an embryo.

According to particular embodiments, the non-human gamete is a non-human sperm. In particular embodiments, the non-human sperm has been produced by a male cattle, in particular a male cattle selected by the method according to the first aspect of the present invention.

Sperm is the male reproductive cell. In the types of sexual reproduction known as anisogamy and its subtype oogamy, there is a marked difference in the size of the gametes with the smaller one being termed the “male” or sperm. A uniflagellar sperm that is motile is referred to as a spermatozoon, whereas a non-motile sperm cell is referred to as a spermatium. Sperm cannot divide and have a limited life span, but after fusion with egg cells during fertilization, a new organism begins developing, starting as a totipotent zygote.

In one embodiment according to the present invention the non-human sperm is a non-human spermatozoon. In another embodiment according to the present invention, the non-human sperm is a non-human spermatium.

According to particular embodiments, the non-human gamete is a non-human ovum. In another embodiment according to the present invention, the non-human ovum is fertilized. In another embodiment according to the present invention, the non-human ovum is unfertilized. In particular embodiments, the non-human ovum has been isolated from a female milk-producing cattle, in particular from a female cattle, preferably a female milk-producing cattle, selected by the method according to the first aspect of the present invention.

The egg cell, or ovum, is the female reproductive cell (gamete) in oogamous organisms. The egg cell is typically not capable of active movement, and it is much larger (visible to the naked eye) than the motile sperm cells. When egg and sperm fuse, a diploid cell (the zygote) is formed, which gradually grows into a new organism.

In one embodiment according to the present invention, said non-human gamete is selected from the group consisting of bovine gamete, cattle gamete and in particular Norwegian Red cattle gamete.

In one embodiment according to the present invention, said female milk-producing cattle is selected from the group consisting of female milk-producing cattle and female milk-producing Norwegian Red cattle.

According to particular embodiments, the at least one allele is an allele of at least one polymorphism. The at least one polymorphism may be selected from the polymorphisms listed in table 1.

In another embodiment according to the second aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #1 to P #916. In another embodiment according to the second aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481 (C16:0), preferably the at least one allele represents a “non-fat allele” for C16:0. In another embodiment according to the second aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #19, P #34, P #38, P #39, P #141, P #148, P #153, P #233-P #240, P #242-P #246, P #271-P #278, P #280-P #283, P #285, P #289-P #302, P #311-P #334, P #339, P #340, P #343-P #475, P #477-P #481, P #484-P #494, P #497, P #543, P #588, P #589, P #916, P #911, P #14, P #37, P #903 and P #7 (C18:1), preferably the at least one allele represents a “fat allele” for C18:1. In another embodiment according to the second aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #1, P #12, P #15-P #17, P #24, P #41, P #63, P #64, P #69-P #71, P #74-P #79, P #83, P #85-P #87, P #89-P #93, P #97-P #103, P #112-P #118, P #120, P #121, P #123-P #135, P #138-P #141, P #148, P #153-P #168, P #218, P #220-P #226, P #249, P #250, P #253-P #260, P #267, P #495, P #499, P #501, P #503-P #514, P #517-P #539, P #541, P #542, P #544-P #547, P #554-P #585, P #590-P #592, P #595-P #597, P #599-P #614, P #617-P #621, P #623-P #652, P #654-P #669, P #672-P #674, P #676-P #678, P #681, P #682, P #688-P #744, P #746-P #769, P #771-P #813, P #815, P #818-P #824, P #826-P #831 and P #872 (C6:0), preferably the at least one allele represents a “fat allele” for C6:0. In another embodiment according to the second aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #1, P #10-P #12, P #16-P #19, P #40-P #45, P #48, P #49, P #51, P #56-P #60, P #63-P #66, P #68-P #93, P #97, P #99-P #101, P #103-P #108, P #111-P #118, P #120, P #121, P #123-P #218, P #220, P #224-P #231, P #254, P #258, P #259, P #268, P #270, P #285-P #288, P #302, P #495, P #496, P #498-P #539, P #541-P #551, P #554-P #586, P #590-P #594, P #628, P #682 and P #683 (C8:0), preferably the at least one allele represents a “fat allele” for C8:0. In another embodiment according to the second aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #3, P #8-P #10, P #16-P #20, P #49-P #51, P #56-P #62, P #64, P #69-P #72, P #74, P #76-P #78, P #80-P #96, P #104-P #109, P #111-P #115, P #117, P #118, P #120, P #121, P #127, P #128, P #132, P #133, P #136-P #142, P #148-P #153, P #156-P #166, P #224-P #226, P #285-P #288, P #297-P #302, P #490-P #494, P #501-P #514, P #517-P #539, P #541-P #547, P #551, P #554-P #580, P #585, P #586, P #589-P #593, P #628, P #889-P #891, P #899, P #900, P #902-P #916 (C10:0), preferably the at least one allele represents a “fat allele” for C10:0. In another embodiment according to the second aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #3, P #9, P #10, P #16-P #20, P #49-P #53, P #61, P #62, P #64, P #67, P #69-P #72, P #74, P #83, P #85-P #87, P #89-P #96, P #104-P #113, P #115, P #117-P #122, P #127, P #128, P #132, P #133, P #138, P #139, P #141, P #142, P #148-P #151, P #153, P #219, P #224-P #226, P #276, P #285-P #288, P #290-P #302, P #487-P #495, P #497, P #501-P #515, P #517-P #547, P #551, P #554-P #580, P #585, P #586, P #588-P #594, P #887-P #891, P #893-P #916 (C12:0), preferably the at least one allele represents a “fat allele” for C12:0. In another embodiment according to the second aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #9, P #10, P #17-P #19, P #34, P #69, P #70, P #83, P #85, P #117, P #120, P #121, P #127, P #128, P #132, P #133, P #139, P #141, P #148-P #151, P #153, P #224-P #226, P #275, P #276, P #279-P #281, P #284-P #302, P #483-P #494, P #497, P #501-P #514, P #517-P #539, P #541, P #543-P #580, P #584-P #594, P #889-P #892, P #899, P #900, P #902-P #916 (C14:0), preferably the at least one allele represents a “fat allele” for C14:0. In another embodiment according to the second aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #243-P #246, P #314-P #332, P #334-P #340, P #346-P #352, P #354-P #363, P #366-P #392, P #394-P #396, P #398-P #410, P #412-P #475 and P #477-P #481 (C14:1 cis-9), preferably the at least one allele represents a “fat allele” for C14:1 cis-9.

In another embodiment according to the second aspect of the present invention, a desired milk fatty acid composition is decreased amount of C16:0 in milk; and/or increased amount of C18:1 in milk; and/or increased amount of C14:1 cis-9 in milk; and/or increased amount of one or more fatty acids selected from the group consisting of C6:0, C8:0, C10:0, C12:0 and C14:0 in milk; and/or optionally any combination thereof.

According to other particular embodiments, the at least one allele is a “fat allele” or a “non-fat allele”, preferably the latter, for C16:0 of at least one polymorphism selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C18:1 of at least one polymorphism selected from the group consisting of P #19, P #34, P #38, P #39, P #141, P #148, P #153, P #233-P #240, P #242-P #246, P #271-P #278, P #280-P #283, P #285, P #289-P #302, P #311-P #334, P #339, P #340, P #343-P #475, P #477-P #481, P #484-P #494, P #497, P #543, P #588, P #589, P #916, P #911, P #14, P #37, P #903 and P #7.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C6:0 of at least one polymorphism selected from the group consisting of P #1, P #12, P #15-P #17, P #24, P #41, P #63, P #64, P #69-P #71, P #74-P #79, P #83, P #85-P #87, P #89-P #93, P #97-P #103, P #112-P #118, P #120, P #121, P #123-P #135, P #138-P #141, P #148, P #153-P #168, P #218, P #220-P #226, P #249, P #250, P #253-P #260, P #267, P #495, P #499, P #501, P #503-P #514, P #517-P #539, P #541, P #542, P #544-P #547, P #554-P #585, P #590-P #592, P #595-P #597, P #599-P #614, P #617-P #621, P #623-P #652, P #654-P #669, P #672-P #674, P #676-P #678, P #681, P #682, P #688-P #744, P #746-P #769, P #771-P #813, P #815, P #818-P #824, P #826-P #831 and P #872.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C8:0 of at least one polymorphism selected from the group consisting of P #1, P #10-P #12, P #16-P #19, P #40-P #45, P #48, P #49, P #51, P #56-P #60, P #63-P #66, P #68-P #93, P #97, P #99-P #101, P #103-P #108, P #111-P #118, P #120, P #121, P #123-P #218, P #220, P #224-P #231, P #254, P #258, P #259, P #268, P #270, P #285-P #288, P #302, P #495, P #496, P #498-P #539, P #541-P #551, P #554-P #586, P #590-P #594, P #628, P #682 and P #683.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C10:0 of at least one polymorphism selected from the group consisting of P #3, P #8-P #10, P #16-P #20, P #49-P #51, P #56-P #62, P #64, P #69-P #72, P #74, P #76-P #78, P #80-P #96, P #104-P #109, P #111-P #115, P #117, P #118, P #120, P #121, P #127, P #128, P #132, P #133, P #136-P #142, P #148-P #153, P #156-P #166, P #224-P #226, P #285-P #288, P #297-P #302, P #490-P #494, P #501-P #514, P #517-P #539, P #541-P #547, P #551, P #554-P #580, P #585, P #586, P #589-P #593, P #628, P #889-P #891, P #899, P #900, P #902-P #916.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C12:0 of at least one polymorphism selected from the group consisting of P #3, P #9, P #10, P #16-P #20, P #49-P #53, P #61, P #62, P #64, P #67, P #69-P #72, P #74, P #83, P #85-P #87, P #89-P #96, P #104-P #113, P #115, P #117-P #122, P #127, P #128, P #132, P #133, P #138, P #139, P #141, P #142, P #148-P #151, P #153, P #219, P #224-P #226, P #276, P #285-P #288, P #290-P #302, P #487-P #495, P #497, P #501-P #515, P #517-P #547, P #551, P #554-P #580, P #585, P #586, P #588-P #594, P #887-P #891, P #893-P #916.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C14:0 of at least one polymorphism selected from the group consisting of P #9, P #10, P #17-P #19, P #34, P #69, P #70, P #83, P #85, P #117, P #120, P #121, P #127, P #128, P #132, P #133, P #139, P #141, P #148-P #151, P #153, P #224-P #226, P #275, P #276, P #279-P #281, P #284-P #302, P #483-P #494, P #497, P #501-P #514, P #517-P #539, P #541, P #543-P #580, P #584-P #594, P #889-P #892, P #899, P #900, P #902-P #916.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C14:1 cis-9 of at least one polymorphism selected from the group consisting of P #243-P #246, P #314-P #332, P #334-P #340, P #346-P #352, P #354-P #363, P #366-P #392, P #394-P #396, P #398-P #410, P #412-P #475 and P #477-P #481.

It is to be understood that a “fat-allele” for a specific trait is indicative of increased amount of that trait in milk; and a “non-fat allele” for a specific trait is indicative of decreased amount of that trait in milk (“fat allele”, “non-fat allele” and the respective traits are specified in table 1).

According to particular embodiments, the non-human gamete comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 1 to 916; and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 1 to 916 by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition.

In one embodiment according to the present invention, the nucleotide substitution(s) and/or nucleotide deletions (preferably substitutions) are not in the polymorphic site (i.e. position 60) of the derived sequence.

According to particular embodiments, the non-human gamete comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQIDNOs 33, 241-248, 303-312, 314-344, 346-475 and, 477-481 (C16:0); and b) nucleotide sequences which are derived from any one of SEQIDNOs 33, 241-248, 303-312, 314-344, 346-475 and, 477-481 (C16:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “non-fat allele” for C16:0.

According to particular embodiments, the non-human gamete comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 19, 34, 38, 39, 141, 148, 153, 233-240, 242-246, 271-278, 280-283, 285, 289-302, 311-334, 339, 340, 343-475, 477-481, 484-494, 497, 543, 588, 589, 916, 911, 14, 37, 903 and 7 (C18:1); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 19, 34, 38, 39, 141, 148, 153, 233-240, 242-246, 271-278, 280-283, 285, 289-302, 311-334, 339, 340, 343-475, 477-481, 484-494, 497, 543, 588, 589, 916, 911, 14, 37, 903 and 7 (C18:1) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C18:1.

According to particular embodiments, the non-human gamete comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 243-246, 314-332, 334-340, 346-352, 354-363, 366-392, 394-396, 398-410, 412-475 and 477-481 (C14:1 cis-9); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 243-246, 314-332, 334-340, 346-352, 354-363, 366-392, 394-396, 398-410, 412-475 and 477-481 (C14:1 cis-9) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C14:1 cis-9.

According to particular embodiments, the non-human gamete comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 1, 12, 15-17, 24, 41, 63, 64, 69-71, 74-79, 83, 85-87, 89-93, 97-103, 112-118, 120, 121, 123-135, 138-141, 148, 153-168, 218, 220-226, 249, 250, 253-260, 267, 495, 499, 501, 503-514, 517-539, 541, 542, 544-547, 554-585, 590-592, 595-597, 599-614, 617-621, 623-652, 654-669, 672-674, 676-678, 681, 682, 688-744, 746-769, 771-813, 815, 818-824, 826-831 and 872 (C6:0); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 1, 12, 15-17, 24, 41, 63, 64, 69-71, 74-79, 83, 85-87, 89-93, 97-103, 112-118, 120, 121, 123-135, 138-141, 148, 153-168, 218, 220-226, 249, 250, 253-260, 267, 495, 499, 501, 503-514, 517-539, 541, 542, 544-547, 554-585, 590-592, 595-597, 599-614, 617-621, 623-652, 654-669, 672-674, 676-678, 681, 682, 688-744, 746-769, 771-813, 815, 818-824, 826-831 and 872 (C6:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C6:0.

According to particular embodiments, the non-human gamete comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 1, 10-12, 16-19, 40-45, 48, 49, 51, 56-60, 63-66, 68-93, 97, 99-101, 103-108, 111-118, 120, 121, 123-218, 220, 224-231, 254, 258, 259, 268, 270, 285-288, 302, 495, 496, 498-539, 541-551, 554-586, 590-594, 628, 682 and 683 (C8:0); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 1, 10-12, 16-19, 40-45, 48, 49, 51, 56-60, 63-66, 68-93, 97, 99-101, 103-108, 111-118, 120, 121, 123-218, 220, 224-231, 254, 258, 259, 268, 270, 285-288, 302, 495, 496, 498-539, 541-551, 554-586, 590-594, 628, 682 and 683 (C8:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C8:0.

According to particular embodiments, the non-human gamete comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 3, 8-10, 16-20, 49-51, 56-62, 64, 69-72, 74, 76-78, 80-96, 104-109, 111-115, 117, 118, 120, 121, 127, 128, 132, 133, 136-142, 148-153, 156-166, 224-226, 285-288, 297-302, 490-494, 501-514, 517-539, 541-547, 551, 554-580, 585, 586, 589-593, 628, 889-891, 899, 900, 902-916 (C10:0); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 3, 8-10, 16-20, 49-51, 56-62, 64, 69-72, 74, 76-78, 80-96, 104-109, 111-115, 117, 118, 120, 121, 127, 128, 132, 133, 136-142, 148-153, 156-166, 224-226, 285-288, 297-302, 490-494, 501-514, 517-539, 541-547, 551, 554-580, 585, 586, 589-593, 628, 889-891, 899, 900, 902-916 (C10:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C10:0.

According to particular embodiments, the non-human gamete comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 3, 9, 10, 16-20, 49-53, 61, 62, 64, 67, 69-72, 74, 83, 85-87, 89-96, 104-113, 115, 117-122, 127, 128, 132, 133, 138, 139, 141, 142, 148-151, 153, 219, 224-226, 276, 285-288, 290-302, 487-495, 497, 501-515, 517-547, 551, 554-580, 585, 586, 588-594, 887-891, 893-916 (C12:0); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 3, 9, 10, 16-20, 49-53, 61, 62, 64, 67, 69-72, 74, 83, 85-87, 89-96, 104-113, 115, 117-122, 127, 128, 132, 133, 138, 139, 141, 142, 148-151, 153, 219, 224-226, 276, 285-288, 290-302, 487-495, 497, 501-515, 517-547, 551, 554-580, 585, 586, 588-594, 887-891, 893-916 (C12:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C12:0.

According to particular embodiments, the non-human gamete comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 9, 10, 17-19, 34, 69, 70, 83, 85, 117, 120, 121, 127, 128, 132, 133, 139, 141, 148-151, 153, 224-226, 275, 276, 279-281, 284-302, 483-494, 497, 501-514, 517-539, 541, 543-580, 584-594, 889-892, 899, 900, 902-916 (C14:0); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 9, 10, 17-19, 34, 69, 70, 83, 85, 117, 120, 121, 127, 128, 132, 133, 139, 141, 148-151, 153, 224-226, 275, 276, 279-281, 284-302, 483-494, 497, 501-514, 517-539, 541, 543-580, 584-594, 889-892, 899, 900, 902-916 (C14:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C14:0.

Method for Selective Breeding

The present invention provides in a third aspect a method for selective breeding of a cattle, the method comprises:

providing non-human semen or non-human sperm comprising within its genome at least one allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition; and

fertilizing a (suitable) female (milk-producing) cattle, preferably a female (milk-producing) cattle selected by the method according to the first aspect of the present invention, using the non-human semen or non-human sperm.

The present invention provides in an alternative aspect a method for selective breeding of a cattle, the method comprises:

fertilizing a (suitable) female (milk-producing) cattle, preferably a female (milk-producing) cattle selected by the method according to the first aspect of the present invention, using the semen or sperm according to the second aspect of the present invention.

In the context of the present invention, a suitable female (milk-producing) cattle is a cattle that is capable of being fertilized with the semen or sperm in the sense that the sperm fuses with an ovum and thereby initiates development of a new organism.

The cattle referred to in the above method may be male or female. In one embodiment according to the present invention, said cattle is male. In another embodiment according to the present invention, said cattle is a female or a female milk-producing cattle.

In certain embodiments according to the present invention, said cattle is selected from the group consisting of Norwegian Red cattle.

In one embodiment according to the present invention, said (suitable) female (milk-producing) cattle is selected from the group consisting of female milk-producing Norwegian Red cattle.

According to particular embodiments, the method comprises:

providing at least one non-human semen or non-human sperm as defined in the second aspect of the present invention; and

fertilizing a (suitable) female (milk-producing) cattle, preferably a female (milk-producing) cattle selected by the method according to the first aspect of the present invention, using the at least one non-human semen or non-human sperm.

In one embodiment according to the present invention, the (suitable) female (milk-producing) cattle that is to be fertilized using the semen or sperm according to the second aspect of the present invention comprises within its genome at least one allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition.

Nearly all mammals, including non-human mammals such as cattle and in particular Norwegian Red cattle, are diploid organisms and thus possess at least one copy of the polymorphisms of the invention. In a preferred embodiment, the (suitable) female (milk-producing) cattle that is to be fertilized using the semen or sperm according to the second aspect of the present invention is homozygote with respect to the at least one allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In an alternative embodiment, the (suitable) female (milk-producing) cattle that is to be fertilized using the semen or sperm according to the second aspect of the present invention is heterozygote with respect to the at least one allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition.

In one embodiment according to the third aspect of the present invention, the at least one allele is an allele of at least one polymorphism, such as at least one single nucleotide polymorphism (SNP). In a preferred embodiment, the at least one polymorphism is selected from the polymorphisms listed in table 1.

In another embodiment according to the third aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #1 to P #916, such as P #1 to P #310. In another embodiment according to the third aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481 (C16:0), preferably the at least one allele represents a “non-fat allele” for C16:0. In another embodiment according to the third aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #19, P #34, P #38, P #39, P #141, P #148, P #153, P #233-P #240, P #242-P #246, P #271-P #278, P #280-P #283, P #285, P #289-P #302, P #311-P #334, P #339, P #340, P #343-P #475, P #477-P #481, P #484-P #494, P #497, P #543, P #588, P #589, P #916, P #911, P #14, P #37, P #903 and P #7 (C18:1), preferably the at least one allele represents a “fat allele” for C18:1. In another embodiment according to the third aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #1, P #12, P #15-P #17, P #24, P #41, P #63, P #64, P #69-P #71, P #74-P #79, P #83, P #85-P #87, P #89-P #93, P #97-P #103, P #112-P #118, P #120, P #121, P #123-P #135, P #138-P #141, P #148, P #153-P #168, P #218, P #220-P #226, P #249, P #250, P #253-P #260, P #267, P #495, P #499, P #501, P #503-P #514, P #517-P #539, P #541, P #542, P #544-P #547, P #554-P #585, P #590-P #592, P #595-P #597, P #599-P #614, P #617-P #621, P #623-P #652, P #654-P #669, P #672-P #674, P #676-P #678, P #681, P #682, P #688-P #744, P #746-P #769, P #771-P #813, P #815, P #818-P #824, P #826-P #831 and P #872 (C6:0), preferably the at least one allele represents a “fat allele” for C6:0. In another embodiment according to the third aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #1, P #10-P #12, P #16-P #19, P #40-P #45, P #48, P #49, P #51, P #56-P #60, P #63-P #66, P #68-P #93, P #97, P #99-P #101, P #103-P #108, P #111-P #118, P #120, P #121, P #123-P #218, P #220, P #224-P #231, P #254, P #258, P #259, P #268, P #270, P #285-P #288, P #302, P #495, P #496, P #498-P #539, P #541-P #551, P #554-P #586, P #590-P #594, P #628, P #682 and P #683 (C8:0), preferably the at least one allele represents a “fat allele” for C8:0. In another embodiment according to the third aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #3, P #8-P #10, P #16-P #20, P #49-P #51, P #56-P #62, P #64, P #69-P #72, P #74, P #76-P #78, P #80-P #96, P #104-P #109, P #111-P #115, P #117, P #118, P #120, P #121, P #127, P #128, P #132, P #133, P #136-P #142, P #148-P #153, P #156-P #166, P #224-P #226, P #285-P #288, P #297-P #302, P #490-P #494, P #501-P #514, P #517-P #539, P #541-P #547, P #551, P #554-P #580, P #585, P #586, P #589-P #593, P #628, P #889-P #891, P #899, P #900, P #902-P #916 (C10:0), preferably the at least one allele represents a “fat allele” for C10:0. In another embodiment according to the third aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #3, P #9, P #10, P #16-P #20, P #49-P #53, P #61, P #62, P #64, P #67, P #69-P #72, P #74, P #83, P #85-P #87, P #89-P #96, P #104-P #113, P #115, P #117-P #122, P #127, P #128, P #132, P #133, P #138, P #139, P #141, P #142, P #148-P #151, P #153, P #219, P #224-P #226, P #276, P #285-P #288, P #290-P #302, P #487-P #495, P #497, P #501-P #515, P #517-P #547, P #551, P #554-P #580, P #585, P #586, P #588-P #594, P #887-P #891, P #893-P #916 (C12:0), preferably the at least one allele represents a “fat allele” for C12:0. In another embodiment according to the third aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #9, P #10, P #17-P #19, P #34, P #69, P #70, P #83, P #85, P #117, P #120, P #121, P #127, P #128, P #132, P #133, P #139, P #141, P #148-P #151, P #153, P #224-P #226, P #275, P #276, P #279-P #281, P #284-P #302, P #483-P #494, P #497, P #501-P #514, P #517-P #539, P #541, P #543-P #580, P #584-P #594, P #889-P #892, P #899, P #900, P #902-P #916 (C14:0), preferably the at least one allele represents a “fat allele” for C14:0. In another embodiment according to the third aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #243-P #246, P #314-P #332, P #334-P #340, P #346-P #352, P #354-P #363, P #366-P #392, P #394-P #396, P #398-P #410, P #412-P #475 and P #477-P #481 (C14:1 cis-9), preferably the at least one allele represents a “fat allele” for C14:1 cis-9.

In another embodiment according to the third aspect of the present invention, a desired milk fatty acid composition is decreased amount of C16:0 in milk; and/or increased amount of C18:1 in milk; and/or increased amount of C14:1 cis-9 in milk; and/or increased amount of one or more fatty acids selected from the group consisting of C6:0, C8:0, C10:0, C12:0 and C14:0 in milk; and/or optionally any combination thereof.

According to other particular embodiments, the at least one allele is a “fat allele” or a “non-fat allele”, preferably the latter, for C16:0 of at least one polymorphism selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C18:1 of at least one polymorphism selected from the group consisting of P #19, P #34, P #38, P #39, P #141, P #148, P #153, P #233-P #240, P #242-P #246, P #271-P #278, P #280-P #283, P #285, P #289-P #302, P #311-P #334, P #339, P #340, P #343-P #475, P #477-P #481, P #484-P #494, P #497, P #543, P #588, P #589, P #916, P #911, P #14, P #37, P #903 and P #7.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C6:0 of at least one polymorphism selected from the group consisting of P #1, P #12, P #15-P #17, P #24, P #41, P #63, P #64, P #69-P #71, P #74-P #79, P #83, P #85-P #87, P #89-P #93, P #97-P #103, P #112-P #118, P #120, P #121, P #123-P #135, P #138-P #141, P #148, P #153-P #168, P #218, P #220-P #226, P #249, P #250, P #253-P #260, P #267, P #495, P #499, P #501, P #503-P #514, P #517-P #539, P #541, P #542, P #544-P #547, P #554-P #585, P #590-P #592, P #595-P #597, P #599-P #614, P #617-P #621, P #623-P #652, P #654-P #669, P #672-P #674, P #676-P #678, P #681, P #682, P #688-P #744, P #746-P #769, P #771-P #813, P #815, P #818-P #824, P #826-P #831 and P #872.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C8:0 of at least one polymorphism selected from the group consisting of P #1, P #10-P #12, P #16-P #19, P #40-P #45, P #48, P #49, P #51, P #56-P #60, P #63-P #66, P #68-P #93, P #97, P #99-P #101, P #103-P #108, P #111-P #118, P #120, P #121, P #123-P #218, P #220, P #224-P #231, P #254, P #258, P #259, P #268, P #270, P #285-P #288, P #302, P #495, P #496, P #498-P #539, P #541-P #551, P #554-P #586, P #590-P #594, P #628, P #682 and P #683.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C10:0 of at least one polymorphism selected from the group consisting of P #3, P #8-P #10, P #16-P #20, P #49-P #51, P #56-P #62, P #64, P #69-P #72, P #74, P #76-P #78, P #80-P #96, P #104-P #109, P #111-P #115, P #117, P #118, P #120, P #121, P #127, P #128, P #132, P #133, P #136-P #142, P #148-P #153, P #156-P #166, P #224-P #226, P #285-P #288, P #297-P #302, P #490-P #494, P #501-P #514, P #517-P #539, P #541-P #547, P #551, P #554-P #580, P #585, P #586, P #589-P #593, P #628, P #889-P #891, P #899, P #900, P #902-P #916.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C12:0 of at least one polymorphism selected from the group consisting of P #3, P #9, P #10, P #16-P #20, P #49-P #53, P #61, P #62, P #64, P #67, P #69-P #72, P #74, P #83, P #85-P #87, P #89-P #96, P #104-P #113, P #115, P #117-P #122, P #127, P #128, P #132, P #133, P #138, P #139, P #141, P #142, P #148-P #151, P #153, P #219, P #224-P #226, P #276, P #285-P #288, P #290-P #302, P #487-P #495, P #497, P #501-P #515, P #517-P #547, P #551, P #554-P #580, P #585, P #586, P #588-P #594, P #887-P #891, P #893-P #916.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C14:0 of at least one polymorphism selected from the group consisting of P #9, P #10, P #17-P #19, P #34, P #69, P #70, P #83, P #85, P #117, P #120, P #121, P #127, P #128, P #132, P #133, P #139, P #141, P #148-P #151, P #153, P #224-P #226, P #275, P #276, P #279-P #281, P #284-P #302, P #483-P #494, P #497, P #501-P #514, P #517-P #539, P #541, P #543-P #580, P #584-P #594, P #889-P #892, P #899, P #900, P #902-P #916.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C14:1 cis-9 of at least one polymorphism selected from the group consisting of P #243-P #246, P #314-P #332, P #334-P #340, P #346-P #352, P #354-P #363, P #366-P #392, P #394-P #396, P #398-P #410, P #412-P #475 and P #477-P #481.

It is to be understood that a “fat-allele” for a specific trait is indicative of increased amount of that trait in milk; and a “non-fat allele” for a specific trait is indicative of decreased amount of that trait in milk (“fat allele”, “non-fat allele” and the respective traits are specified in table 1).

According to particular embodiments, the (suitable) female (milk-producing) cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 1 to 916, such as SEQ ID NOs: 1 to 310; and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 1 to 916, such as SEQ ID NOs: 1 to 310, by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition.

In one embodiment according to the present invention, the nucleotide substitution(s) and/or nucleotide deletions (preferably substitutions) are not in the polymorphic site (i.e. position 60) of the derived sequence.

According to particular embodiments, the (suitable) female (milk-producing) cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQIDNOs 33, 241-248, 303-312, 314-344, 346-475 and, 477-481 (C16:0); and b) nucleotide sequences which are derived from any one of SEQIDNOs 33, 241-248, 303-312, 314-344, 346-475 and, 477-481 (C16:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “non-fat allele” for C16:0.

According to particular embodiments, the (suitable) female (milk-producing) cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 19, 34, 38, 39, 141, 148, 153, 233-240, 242-246, 271-278, 280-283, 285, 289-302, 311-334, 339, 340, 343-475, 477-481, 484-494, 497, 543, 588, 589, 916, 911, 14, 37, 903 and 7 (C18:1); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 19, 34, 38, 39, 141, 148, 153, 233-240, 242-246, 271-278, 280-283, 285, 289-302, 311-334, 339, 340, 343-475, 477-481, 484-494, 497, 543, 588, 589, 916, 911, 14, 37, 903 and 7 (C18:1) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C18:1.

According to particular embodiments, the (suitable) female (milk-producing) cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 243-246, 314-332, 334-340, 346-352, 354-363, 366-392, 394-396, 398-410, 412-475 and 477-481 (C14:1 cis-9); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 243-246, 314-332, 334-340, 346-352, 354-363, 366-392, 394-396, 398-410, 412-475 and 477-481 (C14:1 cis-9) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C14:1 cis-9.

According to particular embodiments, the (suitable) female (milk-producing) cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 1, 12, 15-17, 24, 41, 63, 64, 69-71, 74-79, 83, 85-87, 89-93, 97-103, 112-118, 120, 121, 123-135, 138-141, 148, 153-168, 218, 220-226, 249, 250, 253-260, 267, 495, 499, 501, 503-514, 517-539, 541, 542, 544-547, 554-585, 590-592, 595-597, 599-614, 617-621, 623-652, 654-669, 672-674, 676-678, 681, 682, 688-744, 746-769, 771-813, 815, 818-824, 826-831 and 872 (C6:0); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 1, 12, 15-17, 24, 41, 63, 64, 69-71, 74-79, 83, 85-87, 89-93, 97-103, 112-118, 120, 121, 123-135, 138-141, 148, 153-168, 218, 220-226, 249, 250, 253-260, 267, 495, 499, 501, 503-514, 517-539, 541, 542, 544-547, 554-585, 590-592, 595-597, 599-614, 617-621, 623-652, 654-669, 672-674, 676-678, 681, 682, 688-744, 746-769, 771-813, 815, 818-824, 826-831 and 872 (C6:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C6:0.

According to particular embodiments, the (suitable) female (milk-producing) cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 1, 10-12, 16-19, 40-45, 48, 49, 51, 56-60, 63-66, 68-93, 97, 99-101, 103-108, 111-118, 120, 121, 123-218, 220, 224-231, 254, 258, 259, 268, 270, 285-288, 302, 495, 496, 498-539, 541-551, 554-586, 590-594, 628, 682 and 683 (C8:0); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 1, 10-12, 16-19, 40-45, 48, 49, 51, 56-60, 63-66, 68-93, 97, 99-101, 103-108, 111-118, 120, 121, 123-218, 220, 224-231, 254, 258, 259, 268, 270, 285-288, 302, 495, 496, 498-539, 541-551, 554-586, 590-594, 628, 682 and 683 (C8:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C8:0.

According to particular embodiments, the (suitable) female (milk-producing) cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 3, 8-10, 16-20, 49-51, 56-62, 64, 69-72, 74, 76-78, 80-96, 104-109, 111-115, 117, 118, 120, 121, 127, 128, 132, 133, 136-142, 148-153, 156-166, 224-226, 285-288, 297-302, 490-494, 501-514, 517-539, 541-547, 551, 554-580, 585, 586, 589-593, 628, 889-891, 899, 900, 902-916 (C10:0); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 3, 8-10, 16-20, 49-51, 56-62, 64, 69-72, 74, 76-78, 80-96, 104-109, 111-115, 117, 118, 120, 121, 127, 128, 132, 133, 136-142, 148-153, 156-166, 224-226, 285-288, 297-302, 490-494, 501-514, 517-539, 541-547, 551, 554-580, 585, 586, 589-593, 628, 889-891, 899, 900, 902-916 (C10:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C10:0.

According to particular embodiments, the (suitable) female (milk-producing) cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 3, 9, 10, 16-20, 49-53, 61, 62, 64, 67, 69-72, 74, 83, 85-87, 89-96, 104-113, 115, 117-122, 127, 128, 132, 133, 138, 139, 141, 142, 148-151, 153, 219, 224-226, 276, 285-288, 290-302, 487-495, 497, 501-515, 517-547, 551, 554-580, 585, 586, 588-594, 887-891, 893-916 (C12:0); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 3, 9, 10, 16-20, 49-53, 61, 62, 64, 67, 69-72, 74, 83, 85-87, 89-96, 104-113, 115, 117-122, 127, 128, 132, 133, 138, 139, 141, 142, 148-151, 153, 219, 224-226, 276, 285-288, 290-302, 487-495, 497, 501-515, 517-547, 551, 554-580, 585, 586, 588-594, 887-891, 893-916 (C12:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C12:0.

According to particular embodiments, the (suitable) female (milk-producing) cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 9, 10, 17-19, 34, 69, 70, 83, 85, 117, 120, 121, 127, 128, 132, 133, 139, 141, 148-151, 153, 224-226, 275, 276, 279-281, 284-302, 483-494, 497, 501-514, 517-539, 541, 543-580, 584-594, 889-892, 899, 900, 902-916 (C14:0); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 9, 10, 17-19, 34, 69, 70, 83, 85, 117, 120, 121, 127, 128, 132, 133, 139, 141, 148-151, 153, 224-226, 275, 276, 279-281, 284-302, 483-494, 497, 501-514, 517-539, 541, 543-580, 584-594, 889-892, 899, 900, 902-916 (C14:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C14:0.

In Vitro Method for Selective Breeding

The present invention provides in a fourth aspect a method for selective breeding of a cattle, the method comprises:

in vitro fertilizing the non-human ovum defined in the second aspect of the present invention using the non-human semen or non-human sperm defined in the second aspect of the present invention; and

implanting the in vitro fertilized non-human ovum in the uterus of a (suitable) female (milk-producing) cattle.

An alternative aspect of the present invention relates to a method for selective breeding of a cattle, the method comprises:

providing non-human ovum such as cattle ovum, comprising within its genome at least one allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition;

providing non-human semen or non-human sperm comprising within its genome at least one allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition;

in vitro fertilizing the non-human ovum using the non-human semen or non-human sperm; and

implanting the in vitro fertilized non-human ovum in the uterus of a (suitable) female (milk-producing) cattle.

In vitro fertilization is a process by which an ovum is fertilized by semen or sperm outside the body. The process typically involves monitoring and stimulating a cattle's ovulatory process, removing an ovum from the animal's ovaries and letting semen or sperm fertilize them in a liquid in a laboratory. The fertilized ovum is typically cultured for some days, e.g. 2-6 days, in a growth medium and is then implanted in the same or another female cattle's uterus, with the intention of establishing a successful pregnancy.

In the context of in vitro fertilization, a suitable female (milk-producing) cattle is a cattle that is capable of being implanted with an in vitro fertilized non-human ovum in the sense that the in vitro fertilized non-human ovum develops into a new individual organisms within the body of the suitable female (milk-producing) cattle.

According to particular embodiments, the method comprises:

providing a non-human semen or non-human sperm as defined in the second aspect of the present invention;

providing a non-human ovum as defined in the second aspect of the present invention;

in vitro fertilizing the ovum using the non-human semen or non-human sperm; and

implanting the in vitro fertilized ovum in the uterus of a (suitable) female (milk-producing) cattle.

Cattle

The present invention provides in a fifth aspect, a cattle obtainable by the method according to the first aspect of the present invention, the method according to the third aspect of the present invention or the method according to the fourth aspect of the present invention.

The present invention provides in a sixth aspect, a cattle comprising within its genome at least one allele, such as two, three or four alleles, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition.

The at least one allele referred to in the sixth aspect of the present invention refers to at least one allele which determines a specific phenotype only in female milk-producing cattle. Said cattle may be male or female, but the at least one allele referred to will only determine the specific phenotype in female milk-producing cattle.

A female milk-producing cattle according to the fifth or sixth aspect of the present invention will have a desired milk fatty acid composition. A male cattle according to the fifth or sixth aspect of the present invention possesses a genotype which in a female milk-producing cattle is indicative of a desired milk fatty acid composition and may therefore find use as a breeding animal or as a producer of semen and/or sperm which may be used in various breeding programs.

Since the at least one allele referred to above determines a specific phenotype only in female milk-producing cattle, it has been decided to differentiate between a female cattle, which not necessarily produces milk, and a female milk-producing cattle, which produces milk by definition.

The cattle referred to in the above method may be male or female. In one embodiment according to the present invention, said cattle is male. In another embodiment according to the present invention, said cattle is female, preferably a female milk-producing cattle.

In one embodiment according to the present invention, said cattle is selected from the group consisting of Norwegian Red cattle.

In one embodiment according to the present invention, said female milk-producing cattle is selected from the group consisting of female milk-producing Norwegian Red cattle.

In one embodiment according to the present invention, the cattle is heterozygous with respect to the at least one allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In another embodiment according to the present invention, the cattle is homozygous with respect to the at least one allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition.

In one embodiment according to the sixth aspect of the present invention, the at least one allele is an allele of at least one polymorphism, such as at least one single nucleotide polymorphism (SNP). In a preferred embodiment, the at least one polymorphism is selected from the polymorphisms listed in table 1.

In another embodiment according to the sixth aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #1 to P #916, such as P #1 to P #310. In another embodiment according to the sixth aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481 (C16:0), preferably the at least one allele represents a “non-fat allele” for C16:0. In another embodiment according to the sixth aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #19, P #34, P #38, P #39, P #141, P #148, P #153, P #233-P #240, P #242-P #246, P #271-P #278, P #280-P #283, P #285, P #289-P #302, P #311-P #334, P #339, P #340, P #343-P #475, P #477-P #481, P #484-P #494, P #497, P #543, P #588, P #589, P #916, P #911, P #14, P #37, P #903 and P #7 (C18:1), preferably the at least one allele represents a “fat allele” for C18:1. In another embodiment according to the sixth aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #1, P #12, P #15-P #17, P #24, P #41, P #63, P #64, P #69-P #71, P #74-P #79, P #83, P #85-P #87, P #89-P #93, P #97-P #103, P #112-P #118, P #120, P #121, P #123-P #135, P #138-P #141, P #148, P #153-P #168, P #218, P #220-P #226, P #249, P #250, P #253-P #260, P #267, P #495, P #499, P #501, P #503-P #514, P #517-P #539, P #541, P #542, P #544-P #547, P #554-P #585, P #590-P #592, P #595-P #597, P #599-P #614, P #617-P #621, P #623-P #652, P #654-P #669, P #672-P #674, P #676-P #678, P #681, P #682, P #688-P #744, P #746-P #769, P #771-P #813, P #815, P #818-P #824, P #826-P #831 and P #872 (C6:0), preferably the at least one allele represents a “fat allele” for C6:0. In another embodiment according to the sixth aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #1, P #10-P #12, P #16-P #19, P #40-P #45, P #48, P #49, P #51, P #56-P #60, P #63-P #66, P #68-P #93, P #97, P #99-P #101, P #103-P #108, P #111-P #118, P #120, P #121, P #123-P #218, P #220, P #224-P #231, P #254, P #258, P #259, P #268, P #270, P #285-P #288, P #302, P #495, P #496, P #498-P #539, P #541-P #551, P #554-P #586, P #590-P #594, P #628, P #682 and P #683 (C8:0), preferably the at least one allele represents a “fat allele” for C8:0. In another embodiment according to the sixth aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #3, P #8-P #10, P #16-P #20, P #49-P #51, P #56-P #62, P #64, P #69-P #72, P #74, P #76-P #78, P #80-P #96, P #104-P #109, P #111-P #115, P #117, P #118, P #120, P #121, P #127, P #128, P #132, P #133, P #136-P #142, P #148-P #153, P #156-P #166, P #224-P #226, P #285-P #288, P #297-P #302, P #490-P #494, P #501-P #514, P #517-P #539, P #541-P #547, P #551, P #554-P #580, P #585, P #586, P #589-P #593, P #628, P #889-P #891, P #899, P #900, P #902-P #916 (C10:0), preferably the at least one allele represents a “fat allele” for C10:0. In another embodiment according to the sixth aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #3, P #9, P #10, P #16-P #20, P #49-P #53, P #61, P #62, P #64, P #67, P #69-P #72, P #74, P #83, P #85-P #87, P #89-P #96, P #104-P #113, P #115, P #117-P #122, P #127, P #128, P #132, P #133, P #138, P #139, P #141, P #142, P #148-P #151, P #153, P #219, P #224-P #226, P #276, P #285-P #288, P #290-P #302, P #487-P #495, P #497, P #501-P #515, P #517-P #547, P #551, P #554-P #580, P #585, P #586, P #588-P #594, P #887-P #891, P #893-P #916 (C12:0), preferably the at least one allele represents a “fat allele” for C12:0. In another embodiment according to the sixth aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #9, P #10, P #17-P #19, P #34, P #69, P #70, P #83, P #85, P #117, P #120, P #121, P #127, P #128, P #132, P #133, P #139, P #141, P #148-P #151, P #153, P #224-P #226, P #275, P #276, P #279-P #281, P #284-P #302, P #483-P #494, P #497, P #501-P #514, P #517-P #539, P #541, P #543-P #580, P #584-P #594, P #889-P #892, P #899, P #900, P #902-P #916 (C14:0), preferably the at least one allele represents a “fat allele” for C14:0. In another embodiment according to the sixth aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #243-P #246, P #314-P #332, P #334-P #340, P #346-P #352, P #354-P #363, P #366-P #392, P #394-P #396, P #398-P #410, P #412-P #475 and P #477-P #481 (C14:1 cis-9), preferably the at least one allele represents a “fat allele” for C14:1 cis-9.

In another embodiment according to the sixth aspect of the present invention, a desired milk fatty acid composition is decreased amount of C16:0 in milk; and/or increased amount of C18:1 in milk; and/or increased amount of C14:1 cis-9 in milk; and/or increased amount of one or more fatty acids selected from the group consisting of C6:0, C8:0, C10:0, C12:0 and C14:0 in milk; and/or optionally any combination thereof.

According to other particular embodiments, the at least one allele is a “fat allele” or a “non-fat allele”, preferably the latter, for C16:0 of at least one polymorphism selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C18:1 of at least one polymorphism selected from the group consisting of P #19, P #34, P #38, P #39, P #141, P #148, P #153, P #233-P #240, P #242-P #246, P #271-P #278, P #280-P #283, P #285, P #289-P #302, P #311-P #334, P #339, P #340, P #343-P #475, P #477-P #481, P #484-P #494, P #497, P #543, P #588, P #589, P #916, P #911, P #14, P #37, P #903 and P #7.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C6:0 of at least one polymorphism selected from the group consisting of P #1, P #12, P #15-P #17, P #24, P #41, P #63, P #64, P #69-P #71, P #74-P #79, P #83, P #85-P #87, P #89-P #93, P #97-P #103, P #112-P #118, P #120, P #121, P #123-P #135, P #138-P #141, P #148, P #153-P #168, P #218, P #220-P #226, P #249, P #250, P #253-P #260, P #267, P #495, P #499, P #501, P #503-P #514, P #517-P #539, P #541, P #542, P #544-P #547, P #554-P #585, P #590-P #592, P #595-P #597, P #599-P #614, P #617-P #621, P #623-P #652, P #654-P #669, P #672-P #674, P #676-P #678, P #681, P #682, P #688-P #744, P #746-P #769, P #771-P #813, P #815, P #818-P #824, P #826-P #831 and P #872.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C8:0 of at least one polymorphism selected from the group consisting of P #1, P #10-P #12, P #16-P #19, P #40-P #45, P #48, P #49, P #51, P #56-P #60, P #63-P #66, P #68-P #93, P #97, P #99-P #101, P #103-P #108, P #111-P #118, P #120, P #121, P #123-P #218, P #220, P #224-P #231, P #254, P #258, P #259, P #268, P #270, P #285-P #288, P #302, P #495, P #496, P #498-P #539, P #541-P #551, P #554-P #586, P #590-P #594, P #628, P #682 and P #683.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C10:0 of at least one polymorphism selected from the group consisting of P #3, P #8-P #10, P #16-P #20, P #49-P #51, P #56-P #62, P #64, P #69-P #72, P #74, P #76-P #78, P #80-P #96, P #104-P #109, P #111-P #115, P #117, P #118, P #120, P #121, P #127, P #128, P #132, P #133, P #136-P #142, P #148-P #153, P #156-P #166, P #224-P #226, P #285-P #288, P #297-P #302, P #490-P #494, P #501-P #514, P #517-P #539, P #541-P #547, P #551, P #554-P #580, P #585, P #586, P #589-P #593, P #628, P #889-P #891, P #899, P #900, P #902-P #916.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C12:0 of at least one polymorphism selected from the group consisting of P #3, P #9, P #10, P #16-P #20, P #49-P #53, P #61, P #62, P #64, P #67, P #69-P #72, P #74, P #83, P #85-P #87, P #89-P #96, P #104-P #113, P #115, P #117-P #122, P #127, P #128, P #132, P #133, P #138, P #139, P #141, P #142, P #148-P #151, P #153, P #219, P #224-P #226, P #276, P #285-P #288, P #290-P #302, P #487-P #495, P #497, P #501-P #515, P #517-P #547, P #551, P #554-P #580, P #585, P #586, P #588-P #594, P #887-P #891, P #893-P #916.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C14:0 of at least one polymorphism selected from the group consisting of P #9, P #10, P #17-P #19, P #34, P #69, P #70, P #83, P #85, P #117, P #120, P #121, P #127, P #128, P #132, P #133, P #139, P #141, P #148-P #151, P #153, P #224-P #226, P #275, P #276, P #279-P #281, P #284-P #302, P #483-P #494, P #497, P #501-P #514, P #517-P #539, P #541, P #543-P #580, P #584-P #594, P #889-P #892, P #899, P #900, P #902-P #916.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C14:1 cis-9 of at least one polymorphism selected from the group consisting of P #243-P #246, P #314-P #332, P #334-P #340, P #346-P #352, P #354-P #363, P #366-P #392, P #394-P #396, P #398-P #410, P #412-P #475 and P #477-P #481.

It is to be understood that a “fat-allele” for a specific trait is indicative of increased amount of that trait in milk; and a “non-fat allele” for a specific trait is indicative of decreased amount of that trait in milk (“fat allele”, “non-fat allele” and the respective traits are specified in table 1).

According to particular embodiments, the cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 1 to 916, such as SEQ ID NOs: 1 to 310; and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 1 to 916, such as SEQ ID NOs: 1 to 310, by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition.

In one embodiment according to the present invention, the nucleotide substitution(s) and/or nucleotide deletions (preferably substitutions) are not in the polymorphic site (i.e. position 60) of the derived sequence.

According to particular embodiments, the cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQIDNOs 33, 241-248, 303-312, 314-344, 346-475 and, 477-481 (C16:0); and b) nucleotide sequences which are derived from any one of SEQIDNOs 33, 241-248, 303-312, 314-344, 346-475 and, 477-481 (C16:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “non-fat allele” for C16:0.

According to particular embodiments, the cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 19, 34, 38, 39, 141, 148, 153, 233-240, 242-246, 271-278, 280-283, 285, 289-302, 311-334, 339, 340, 343-475, 477-481, 484-494, 497, 543, 588, 589, 916, 911, 14, 37, 903 and 7 (C18:1); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 19, 34, 38, 39, 141, 148, 153, 233-240, 242-246, 271-278, 280-283, 285, 289-302, 311-334, 339, 340, 343-475, 477-481, 484-494, 497, 543, 588, 589, 916, 911, 14, 37, 903 and 7 (C18:1) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C18:1.

According to particular embodiments, the cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 243-246, 314-332, 334-340, 346-352, 354-363, 366-392, 394-396, 398-410, 412-475 and 477-481 (C14:1 cis-9); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 243-246, 314-332, 334-340, 346-352, 354-363, 366-392, 394-396, 398-410, 412-475 and 477-481 (C14:1 cis-9) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C14:1 cis-9.

According to particular embodiments, the cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 1, 12, 15-17, 24, 41, 63, 64, 69-71, 74-79, 83, 85-87, 89-93, 97-103, 112-118, 120, 121, 123-135, 138-141, 148, 153-168, 218, 220-226, 249, 250, 253-260, 267, 495, 499, 501, 503-514, 517-539, 541, 542, 544-547, 554-585, 590-592, 595-597, 599-614, 617-621, 623-652, 654-669, 672-674, 676-678, 681, 682, 688-744, 746-769, 771-813, 815, 818-824, 826-831 and 872 (C6:0); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 1, 12, 15-17, 24, 41, 63, 64, 69-71, 74-79, 83, 85-87, 89-93, 97-103, 112-118, 120, 121, 123-135, 138-141, 148, 153-168, 218, 220-226, 249, 250, 253-260, 267, 495, 499, 501, 503-514, 517-539, 541, 542, 544-547, 554-585, 590-592, 595-597, 599-614, 617-621, 623-652, 654-669, 672-674, 676-678, 681, 682, 688-744, 746-769, 771-813, 815, 818-824, 826-831 and 872 (C6:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C6:0.

According to particular embodiments, the cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 1, 10-12, 16-19, 40-45, 48, 49, 51, 56-60, 63-66, 68-93, 97, 99-101, 103-108, 111-118, 120, 121, 123-218, 220, 224-231, 254, 258, 259, 268, 270, 285-288, 302, 495, 496, 498-539, 541-551, 554-586, 590-594, 628, 682 and 683 (C8:0); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 1, 10-12, 16-19, 40-45, 48, 49, 51, 56-60, 63-66, 68-93, 97, 99-101, 103-108, 111-118, 120, 121, 123-218, 220, 224-231, 254, 258, 259, 268, 270, 285-288, 302, 495, 496, 498-539, 541-551, 554-586, 590-594, 628, 682 and 683 (C8:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C8:0.

According to particular embodiments, the cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 3, 8-10, 16-20, 49-51, 56-62, 64, 69-72, 74, 76-78, 80-96, 104-109, 111-115, 117, 118, 120, 121, 127, 128, 132, 133, 136-142, 148-153, 156-166, 224-226, 285-288, 297-302, 490-494, 501-514, 517-539, 541-547, 551, 554-580, 585, 586, 589-593, 628, 889-891, 899, 900, 902-916 (C10:0); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 3, 8-10, 16-20, 49-51, 56-62, 64, 69-72, 74, 76-78, 80-96, 104-109, 111-115, 117, 118, 120, 121, 127, 128, 132, 133, 136-142, 148-153, 156-166, 224-226, 285-288, 297-302, 490-494, 501-514, 517-539, 541-547, 551, 554-580, 585, 586, 589-593, 628, 889-891, 899, 900, 902-916 (C10:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C10:0.

According to particular embodiments, the cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 3, 9, 10, 16-20, 49-53, 61, 62, 64, 67, 69-72, 74, 83, 85-87, 89-96, 104-113, 115, 117-122, 127, 128, 132, 133, 138, 139, 141, 142, 148-151, 153, 219, 224-226, 276, 285-288, 290-302, 487-495, 497, 501-515, 517-547, 551, 554-580, 585, 586, 588-594, 887-891, 893-916 (C12:0); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 3, 9, 10, 16-20, 49-53, 61, 62, 64, 67, 69-72, 74, 83, 85-87, 89-96, 104-113, 115, 117-122, 127, 128, 132, 133, 138, 139, 141, 142, 148-151, 153, 219, 224-226, 276, 285-288, 290-302, 487-495, 497, 501-515, 517-547, 551, 554-580, 585, 586, 588-594, 887-891, 893-916 (C12:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C12:0.

According to particular embodiments, the cattle comprises within its genome at least one nucleotide sequence selected from the group consisting of a) the nucleotide sequences set forth in any one of SEQ ID NOs: 9, 10, 17-19, 34, 69, 70, 83, 85, 117, 120, 121, 127, 128, 132, 133, 139, 141, 148-151, 153, 224-226, 275, 276, 279-281, 284-302, 483-494, 497, 501-514, 517-539, 541, 543-580, 584-594, 889-892, 899, 900, 902-916 (C14:0); and b) nucleotide sequences which are derived from any one of SEQ ID NOs: 9, 10, 17-19, 34, 69, 70, 83, 85, 117, 120, 121, 127, 128, 132, 133, 139, 141, 148-151, 153, 224-226, 275, 276, 279-281, 284-302, 483-494, 497, 501-514, 517-539, 541, 543-580, 584-594, 889-892, 899, 900, 902-916 (C14:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions);

wherein

the one or more nucleotides at position 60 of said nucleotide sequences is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition. In one embodiment, the one or more nucleotides at position 60 of the nucleotide sequences correspond to the “fat allele” for C14:0.

Milk

Bovine milk is widely regarded as a valuable food source in human nutrition, and serves as an important source of proteins, minerals, vitamins and fats in western diets. In addition to being an important source of energy, the milk fat contains valuable fat-soluble vitamins and bio-active lipid components. Of the roughly 400 different fatty acids found in Bovine milk, only around 15 are present at the 1% level or higher.

The present invention provides female milk-producing cattle which herein have been shown to be associated with a desired milk fatty acid composition.

Thus, a seventh aspect of the present invention, relates to milk produced by the female milk-producing cattle according to the fifth or sixth aspect of the present invention.

Use

The present invention provides in an eighth aspect, use of an (isolated) nucleic acid molecule in an in vitro method for determining the presence of at least one allele, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of a cattle;

wherein

the (isolated) nucleic acid molecule comprises at least one nucleotide sequence selected from the group consisting of a) a nucleotide sequence set forth in any one of SEQ ID NO: 1 to 916, such as SEQ ID NOs: 1 to 310; b) a nucleotide sequence derived from any one of SEQ ID NO: 1 to 916, such as SEQ ID NOs: 1 to 310, by 1 to 30, such as 1 to 20, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions); and c) complements to a) and b); the one or more nucleotides at position 60 of said nucleotide sequences being selected from the two alternative forms of the allele to be determined.

It is to be understood that the at least one allele is an allele of at least one polymorphism selected from the polymorphisms listed in table 1.

If the at least one allele to be determined is an allele of P #1, then the isolated nucleic acid molecule comprises a nucleotide sequence selected from the group consisting of a) a nucleotide sequence set forth in SEQ ID NO: 1; b) a nucleotide sequence derived from SEQ ID NO: 1 by 1 to 30, such as 1 to 20, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions); and c) complements to a) and b). If the at least one allele to be determined corresponds to the “fat allele” of P #1, the nucleotide at position 60 of SEQIDNO1 is a guanine. If the at least one allele to be determined corresponds to the “non-fat allele” of P #1, the nucleotide at position 60 of SEQIDNO1 is an adenine.

If the at least one allele to be determined is an allele of P #10, then the isolated nucleic acid molecule comprises a nucleotide sequence selected from the group consisting of a) a nucleotide sequence set forth in SEQ ID NO: 10; b) a nucleotide sequence derived from SEQ ID NO: 10 by 1 to 30, such as 1 to 20, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions); and c) complements to a) and b).

In view of the above examples and the information provided in table 1 and table 2, a man skilled in the art will easily know what nucleic acid molecule to use in order to determine the presence of an allele of a polymorphism selected from the polymorphisms listed in table 1.

The nucleic acid molecule may have a length of at least 119 nucleotides, such as at least 120 nucleotides, at least 121 nucleotides, at least 130 nucleotides or at least 140 nucleotides or at least 150 nucleotides, at least 160 nucleotides or even more than 160 nucleotides.

According to certain embodiments, the nucleic acid molecule has a length from 119 nucleotides to 400 nucleotides, such as from 119 nucleotides to 300 nucleotides or from 119 to 200 nucleotides, e.g. from 119 to 150 nucleotides.

According to certain embodiments, the nucleic acid molecule has a length from 120 nucleotides to 400 nucleotides, such as from 120 nucleotides to 300 nucleotides or from 120 to 200 nucleotides, e.g. from 120 to 150 nucleotides.

According to certain embodiments, the nucleic acid molecule has a length from 121 nucleotides to 400 nucleotides, such as from 121 nucleotides to 300 nucleotides or from 121 to 200 nucleotides, e.g. from 121 to 150 nucleotides.

It is to be understood that the above use involves analyzing a biological sample from a cattle for the presence of at least one allele, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition.

The present invention provides in a ninth aspect, use of an (isolated) oligonucleotide in an in vitro method for determining the presence of at least one allele, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of a cattle;

wherein the (isolated) oligonucleotide comprises at least 8 contiguous nucleotides of a nucleotide sequence selected from the group consisting of a) a nucleotide sequence set forth in any one of SEQ ID NO: 1 to 916, such as SEQ ID NOs: 1 to 310; b) a nucleotide sequence derived from any one of SEQ ID NO: 1 to 916, such as SEQ ID NOs: 1 to 310, by 1 to 30, such as 1 to 20, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions); and c) complements to a) and b); said at least 8 contiguous nucleotides include the one or more nucleotides at position 60 of a) or b); and the one or more nucleotides at position 60 of said nucleotide sequences being selected from the two alternative forms of the allele to be determined.

It is to be understood that the at least one allele is an allele of at least one polymorphism selected from the polymorphisms listed in table 1.

If the at least one allele to be determined is an allele of P #1, then the isolated oligonucleotide comprises at least 8 contiguous nucleotides of a nucleotide sequence selected from the group consisting of a) a nucleotide sequence set forth in SEQ ID NO: 1; b) a nucleotide sequence derived from SEQ ID NO: 1 by 1 to 30, such as 1 to 20, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions); and c) complements to a) and b); said at least 8 contiguous nucleotides include the one or more nucleotides at position 60 of a) or b).

If the at least one allele to be determined is an allele of P #10, then the isolated oligonucleotide comprises at least 8 contiguous nucleotides of a nucleotide sequence selected from the group consisting of a) a nucleotide sequence set forth in SEQ ID NO: 10; b) a nucleotide sequence derived from SEQ ID NO: 10 by 1 to 30, such as 1 to 20, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions); and c) complements to a) and b); said at least 8 contiguous nucleotides include the one or more nucleotides at position 60 of a) or b).

In view of the above examples and the information provided in table 1 and table 2, a man skilled in the art will easily know what oligonucleotide to use in order to determine the presence of an allele of a polymorphism selected from the polymorphisms listed in table 1.

It is to be understood that the above use involves analyzing a biological sample from a cattle for the presence of at least one allele, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition.

As used herein, an “oligonucleotide” is a plurality of joined nucleotides joined by native phosphodiester bonds, typically from 8 to 300 nucleotides in length.

According to certain embodiments, the oligonucleotide or complement thereof has a length of at least 8 nucleotides, such as at least 10 nucleotides.

According to certain embodiments, the oligonucleotide or complement thereof has a length of at least 15 nucleotides, such as at least 20 nucleotides.

According to certain embodiments, the oligonucleotide or complement thereof has a length of at least 30 nucleotides, such as at least 40 nucleotides.

According to certain embodiments, the oligonucleotide or complement thereof has a length of at least 50 nucleotides, such as at least 60 nucleotides.

According to certain embodiments, the oligonucleotide or complement thereof has a length of at least 70 nucleotides, such as at least 80 nucleotides.

According to certain embodiments, the oligonucleotide or complement thereof has a length of 30 to 200 nucleotides, such as 30 to 150 nucleotides.

According to certain embodiments, the oligonucleotide or complement thereof has a length of 30 to 100 nucleotides, such as 30 to 70 nucleotides.

According to certain embodiments, the oligonucleotide or complement thereof has a length of 30 to 100 nucleotides, such as 30 to 70 nucleotides.

According to certain embodiments, the oligonucleotide or complement thereof has a length of 30 to 50 nucleotides, such as 30 to 40 nucleotides.

According to certain embodiments, the oligonucleotide or complement thereof has a length of 8 to 200 nucleotides, such as 8 to 150 nucleotides.

According to certain embodiments, the oligonucleotide or complement thereof has a length of 8 to 100 nucleotides, such as 8 to 70 nucleotides.

According to certain embodiments, the oligonucleotide or complement thereof has a length of 8 to 100 nucleotides, such as 8 to 70 nucleotides.

According to certain embodiments, the oligonucleotide or complement thereof has a length of 8 to 50 nucleotides, such as 8 to 40 nucleotides.

According to certain embodiments, the oligonucleotide or complement thereof is a primer, such as a PCR primer.

According to certain embodiments, the oligonucleotide or complement thereof is a probe, such as a hybridization probe.

As used herein, “probes” and “primer” are isolated oligonucleotides of at least 8 nucleotides, such as at least 10 nucleotides, capable of hybridizing, preferably hybridizing under stringent conditions, to a target nucleic acid.

The term “hybridization stringency” refers to the degree to which mismatches are tolerated in a hybridization assay. The more stringent the conditions, the more likely mismatched heteroduplexes are to be forced apart, whereas less stringent hybridization conditions enhance the stability of mismatched heteroduplexes. In other words, increasing the stringency increases the specificity of the hybridization reaction. A person skilled in the art is able to select the hybridization conditions such that a desired level of stringency is achieved. Generally, the stringency may be increased by increasing temperatures (closer to the melting temperature (Tm) of the heteroduplex), lowering the salt concentrations, and using organic solvents. As known in the art, stringent hybridization conditions are sequence dependent and, thus, they are different under different experimental parameters.

The hybridization conditions can be chosen such that a single mismatch renders a heteroduplex unstable. Such hybridization conditions may be called as “highly stringent hybridization conditions”.

The Tm is the temperature (under defined ionic strength, pH, and DNA concentration) at which 50% of the target motifs are hybiridized with their matched binding units. Stringent conditions may be obtained by performing the hybridization in a temperature equal or close to the Tm for the probe in question.

Exemplary stringent hybridization conditions for short binding units include 6×SSC, 0.5% Tween20, and 20% form amide incubated at 37° C. in 600 rpm for one hour, followed by washing twice in TBS buffer containing 0.05% Tween20 at room temperature.

According to certain embodiments, the present invention provides a complement to the oligonucleotide specified above. Such complement may be used as a probe, such as a hybridization probe.

A probe or primer according to the present invention may have attached to it a detectable label or reporter molecule. Typical labels include radioactive isotopes, enzyme substrates, co-factors, ligands, chemiluminescent or fluorescent agents, haptens, and enyzmes. Methods for labelling and guidance in the choice of labels appropriate for various purposes are discussed, for example, in Sambrook et al. (In Molecular Cloning, A Laboratory Manual, CSHL, New York, 1989) and Ausubel et al. (In Current Protocols in Molecular Biology, John Wiley & Sons, New York, 1998). As a particular example, a probe or primer may include one fluorophor, such as an acceptor fluorophore or donor fluorophor. Such fluorophore may be attached at the 5′- or 3′ end of the probe/primer.

Probes are generally at least 15 nucleotides in length, such as at least 16, at least 17, at least 18, at least 19, at least 20, at least 25, at least 30, at least 35, at least 40, at least 45, at least 50, at least 55, at least 60, at least 65, at least 70, or more contiguous nucleotides complementary to the target nucleic acid molecule, such as 20 to 70 nucleotides, 20 to 60 nucleotides, 20 to 50 nucleotides, 20 to 40 nucleotides, or 20 to 30 nucleotides.

Primers are shorter in length. An oligonucleotide used as primer may be at least 10 nucleotides in length. The specificity of a primer increases with its length. Thus, for example, a primer that includes 30 consecutive nucleotides will anneal to a target sequence with a higher specificity that a corresponding primer of only 15 nucleotides. Thus, to obtain greater specificity, primers of the invention are at least 15 nucleotides in length, such as at least 16, at least 17, at least 18, at least 19, at least 20, at least 25, at least 30, at least 35, at least 40, at least 45, at least 50, at least 55, at least 60, at least 65, at least 70, or more contiguous nucleotides complementary to the target nucleic acid molecule, such as 15 to 70 nucleotides, 15 to 60 nucleotides, 15 to 50 nucleotides, 15 to 40 nucleotides, or 15 to 30 nucleotides. Primer pairs can be used for amplification of nucleic acid sequences, for example, by PCT, real-time-PCR, or other nucleic-acid amplification methods known in the art.

Method for Predicting

The present invention provides in an alternative aspect a method for predicting milk fatty acid composition in a female milk-producing cattle, the method comprises:

determining the presence of at least one allele, such as at least two, three or four alleles, which in a female milk-producing cattle is indicative of altered milk fatty acid composition, within the genome of said female milk-producing cattle.

In one embodiment according to the present invention, said female milk-producing cattle is female milk-producing cattle and in particular Norwegian Red cattle.

In one embodiment according to the alternative aspect of the present invention, the at least one allele is an allele of at least one polymorphism, such as at least one single nucleotide polymorphism (SNP). In a preferred embodiment, the at least one polymorphism is selected from the polymorphisms listed in table 1.

In another embodiment according to the alternative aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #1 to P #916, such as P #1 to P #310. In another embodiment according to the alternative aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481 (C16:0), preferably the at least one allele represents a “non-fat allele” for C16:0. In another embodiment according to the alternative aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #19, P #34, P #38, P #39, P #141, P #148, P #153, P #233-P #240, P #242-P #246, P #271-P #278, P #280-P #283, P #285, P #289-P #302, P #311-P #334, P #339, P #340, P #343-P #475, P #477-P #481, P #484-P #494, P #497, P #543, P #588, P #589, P #916, P #911, P #14, P #37, P #903 and P #7 (C18:1), preferably the at least one allele represents a “fat allele” for C18:1. In another embodiment according to the alternative aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #1, P #12, P #15-P #17, P #24, P #41, P #63, P #64, P #69-P #71, P #74-P #79, P #83, P #85-P #87, P #89-P #93, P #97-P #103, P #112-P #118, P #120, P #121, P #123-P #135, P #138-P #141, P #148, P #153-P #168, P #218, P #220-P #226, P #249, P #250, P #253-P #260, P #267, P #495, P #499, P #501, P #503-P #514, P #517-P #539, P #541, P #542, P #544-P #547, P #554-P #585, P #590-P #592, P #595-P #597, P #599-P #614, P #617-P #621, P #623-P #652, P #654-P #669, P #672-P #674, P #676-P #678, P #681, P #682, P #688-P #744, P #746-P #769, P #771-P #813, P #815, P #818-P #824, P #826-P #831 and P #872 (C6:0), preferably the at least one allele represents a “fat allele” for C6:0. In another embodiment according to the alternative aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #1, P #10-P #12, P #16-P #19, P #40-P #45, P #48, P #49, P #51, P #56-P #60, P #63-P #66, P #68-P #93, P #97, P #99-P #101, P #103-P #108, P #111-P #118, P #120, P #121, P #123-P #218, P #220, P #224-P #231, P #254, P #258, P #259, P #268, P #270, P #285-P #288, P #302, P #495, P #496, P #498-P #539, P #541-P #551, P #554-P #586, P #590-P #594, P #628, P #682 and P #683 (C8:0), preferably the at least one allele represents a “fat allele” for C8:0. In another embodiment according to the alternative aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #3, P #8-P #10, P #16-P #20, P #49-P #51, P #56-P #62, P #64, P #69-P #72, P #74, P #76-P #78, P #80-P #96, P #104-P #109, P #111-P #115, P #117, P #118, P #120, P #121, P #127, P #128, P #132, P #133, P #136-P #142, P #148-P #153, P #156-P #166, P #224-P #226, P #285-P #288, P #297-P #302, P #490-P #494, P #501-P #514, P #517-P #539, P #541-P #547, P #551, P #554-P #580, P #585, P #586, P #589-P #593, P #628, P #889-P #891, P #899, P #900, P #902-P #916 (C10:0), preferably the at least one allele represents a “fat allele” for C10:0. In another embodiment according to the alternative aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #3, P #9, P #10, P #16-P #20, P #49-P #53, P #61, P #62, P #64, P #67, P #69-P #72, P #74, P #83, P #85-P #87, P #89-P #96, P #104-P #113, P #115, P #117-P #122, P #127, P #128, P #132, P #133, P #138, P #139, P #141, P #142, P #148-P #151, P #153, P #219, P #224-P #226, P #276, P #285-P #288, P #290-P #302, P #487-P #495, P #497, P #501-P #515, P #517-P #547, P #551, P #554-P #580, P #585, P #586, P #588-P #594, P #887-P #891, P #893-P #916 (C12:0), preferably the at least one allele represents a “fat allele” for C12:0. In another embodiment according to the alternative aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #9, P #10, P #17-P #19, P #34, P #69, P #70, P #83, P #85, P #117, P #120, P #121, P #127, P #128, P #132, P #133, P #139, P #141, P #148-P #151, P #153, P #224-P #226, P #275, P #276, P #279-P #281, P #284-P #302, P #483-P #494, P #497, P #501-P #514, P #517-P #539, P #541, P #543-P #580, P #584-P #594, P #889-P #892, P #899, P #900, P #902-P #916 (C14:0), preferably the at least one allele represents a “fat allele” for C14:0.

In another embodiment according to the alternative aspect of the present invention, the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #243-P #246, P #314-P #332, P #334-P #340, P #346-P #352, P #354-P #363, P #366-P #392, P #394-P #396, P #398-P #410, P #412-P #475 and P #477-P #481 (C14:1 cis-9), preferably the at least one allele represents a “fat allele” for C14:1 cis-9.

In another embodiment according to the alternative aspect of the present invention, altered milk fatty acid composition is decreased amount of C16:0 in milk; and/or increased amount of C18:1 in milk; and/or increased amount of C14:1 cis-9 in milk; and/or increased amount of one or more fatty acids selected from the group consisting of C6:0, C8:0, C10:0, C12:0 and C14:0 in milk; and/or optionally any combination thereof.

According to other particular embodiments, the at least one allele is a “fat allele” or a “non-fat allele”, preferably the latter, for C16:0 of at least one polymorphism selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C18:1 of at least one polymorphism selected from the group consisting of P #19, P #34, P #38, P #39, P #141, P #148, P #153, P #233-P #240, P #242-P #246, P #271-P #278, P #280-P #283, P #285, P #289-P #302, P #311-P #334, P #339, P #340, P #343-P #475, P #477-P #481, P #484-P #494, P #497, P #543, P #588, P #589, P #916, P #911, P #14, P #37, P #903 and P #7.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C6:0 of at least one polymorphism selected from the group consisting of P #1, P #12, P #15-P #17, P #24, P #41, P #63, P #64, P #69-P #71, P #74-P #79, P #83, P #85-P #87, P #89-P #93, P #97-P #103, P #112-P #118, P #120, P #121, P #123-P #135, P #138-P #141, P #148, P #153-P #168, P #218, P #220-P #226, P #249, P #250, P #253-P #260, P #267, P #495, P #499, P #501, P #503-P #514, P #517-P #539, P #541, P #542, P #544-P #547, P #554-P #585, P #590-P #592, P #595-P #597, P #599-P #614, P #617-P #621, P #623-P #652, P #654-P #669, P #672-P #674, P #676-P #678, P #681, P #682, P #688-P #744, P #746-P #769, P #771-P #813, P #815, P #818-P #824, P #826-P #831 and P #872.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C8:0 of at least one polymorphism selected from the group consisting of P #1, P #10-P #12, P #16-P #19, P #40-P #45, P #48, P #49, P #51, P #56-P #60, P #63-P #66, P #68-P #93, P #97, P #99-P #101, P #103-P #108, P #111-P #118, P #120, P #121, P #123-P #218, P #220, P #224-P #231, P #254, P #258, P #259, P #268, P #270, P #285-P #288, P #302, P #495, P #496, P #498-P #539, P #541-P #551, P #554-P #586, P #590-P #594, P #628, P #682 and P #683.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C10:0 of at least one polymorphism selected from the group consisting of P #3, P #8-P #10, P #16-P #20, P #49-P #51, P #56-P #62, P #64, P #69-P #72, P #74, P #76-P #78, P #80-P #96, P #104-P #109, P #111-P #115, P #117, P #118, P #120, P #121, P #127, P #128, P #132, P #133, P #136-P #142, P #148-P #153, P #156-P #166, P #224-P #226, P #285-P #288, P #297-P #302, P #490-P #494, P #501-P #514, P #517-P #539, P #541-P #547, P #551, P #554-P #580, P #585, P #586, P #589-P #593, P #628, P #889-P #891, P #899, P #900, P #902-P #916.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C12:0 of at least one polymorphism selected from the group consisting of P #3, P #9, P #10, P #16-P #20, P #49-P #53, P #61, P #62, P #64, P #67, P #69-P #72, P #74, P #83, P #85-P #87, P #89-P #96, P #104-P #113, P #115, P #117-P #122, P #127, P #128, P #132, P #133, P #138, P #139, P #141, P #142, P #148-P #151, P #153, P #219, P #224-P #226, P #276, P #285-P #288, P #290-P #302, P #487-P #495, P #497, P #501-P #515, P #517-P #547, P #551, P #554-P #580, P #585, P #586, P #588-P #594, P #887-P #891, P #893-P #916.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C14:0 of at least one polymorphism selected from the group consisting of P #9, P #10, P #17-P #19, P #34, P #69, P #70, P #83, P #85, P #117, P #120, P #121, P #127, P #128, P #132, P #133, P #139, P #141, P #148-P #151, P #153, P #224-P #226, P #275, P #276, P #279-P #281, P #284-P #302, P #483-P #494, P #497, P #501-P #514, P #517-P #539, P #541, P #543-P #580, P #584-P #594, P #889-P #892, P #899, P #900, P #902-P #916.

According to other particular embodiments, the at least one allele is a “non-fat allele” or a “fat allele”, preferably the latter, for C14:1 cis-9 of at least one polymorphism selected from the group consisting of P #243-P #246, P #314-P #332, P #334-P #340, P #346-P #352, P #354-P #363, P #366-P #392, P #394-P #396, P #398-P #410, P #412-P #475 and P #477-P #481.

It is to be understood that a “fat-allele” for a specific trait is indicative of increased amount of that trait in milk; and a “non-fat allele” for a specific trait is indicative of decreased amount of that trait in milk (“fat allele”, “non-fat allele” and the respective traits are specified in table 1).

According to other particular embodiments, the present invention provides a method for predicting milk fatty acid composition in a female milk-producing cattle, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NOs: 1 to 916, such as SEQ ID NOs: 1 to 310; or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NOs: 1 to 916, such as SEQ ID NOs: 1 to 310, by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions).

In one embodiment according to the present invention, the nucleotide substitution(s) and/or nucleotide deletions (preferably substitutions) are not in the polymorphic site (i.e. position 60) of the derived sequence.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQIDNOs 33, 241-248, 303-312, 314-344, 346-475 and, 477-481 (C16:0); or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of 33, 241-248, 303-312, 314-344, 346-475 and, 477-481 (C16:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions).

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NOs: 19, 34, 38, 39, 141, 148, 153, 233-240, 242-246, 271-278, 280-283, 285, 289-302, 311-334, 339, 340, 343-475, 477-481, 484-494, 497, 543, 588, 589, 916, 911, 14, 37, 903 and 7 (C18:1); or ata position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NOs: 19, 34, 38, 39, 141, 148, 153, 233-240, 242-246, 271-278, 280-283, 285, 289-302, 311-334, 339, 340, 343-475, 477-481, 484-494, 497, 543, 588, 589, 916, 911, 14, 37, 903 and 7 (C18:1) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions).

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NOs: 243-246, 314-332, 334-340, 346-352, 354-363, 366-392, 394-396, 398-410, 412-475 and 477-481 (C14:1 cis-9); or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NOs: 243-246, 314-332, 334-340, 346-352, 354-363, 366-392, 394-396, 398-410, 412-475 and 477-481 (C14:1 cis-9) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions).

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NOs: 1, 12, 15-17, 24, 41, 63, 64, 69-71, 74-79, 83, 85-87, 89-93, 97-103, 112-118, 120, 121, 123-135, 138-141, 148, 153-168, 218, 220-226, 249, 250, 253-260, 267, 495, 499, 501, 503-514, 517-539, 541, 542, 544-547, 554-585, 590-592, 595-597, 599-614, 617-621, 623-652, 654-669, 672-674, 676-678, 681, 682, 688-744, 746-769, 771-813, 815, 818 824, 826-831 and 872 (C6:0); or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NOs: 1, 12, 15-17, 24, 41, 63, 64, 69-71, 74-79, 83, 85-87, 89-93, 97-103, 112-118, 120, 121, 123-135, 138-141, 148, 153-168, 218, 220-226, 249, 250, 253-260, 267, 495, 499, 501, 503-514, 517-539, 541, 542, 544-547, 554-585, 590-592, 595-597, 599-614, 617-621, 623-652, 654-669, 672-674, 676-678, 681, 682, 688-744, 746-769, 771-813, 815, 818-824, 826-831 and 872 (C6:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions).

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NOs: 1, 10-12, 16-19, 40-45, 48, 49, 51, 56-60, 63-66, 68-93, 97, 99-101, 103-108, 111-118, 120, 121, 123-218, 220, 224-231, 254, 258, 259, 268, 270, 285-288, 302, 495, 496, 498-539, 541-551, 554-586, 590-594, 628, 682 and 683 (C8:0); or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NOs: 1, 10-12, 16-19, 40-45,48,49,51,56-60, 63-66, 68-93,97,99-101, 103-108, 111-118, 120, 121, 123-218, 220, 224-231, 254, 258, 259, 268, 270, 285-288, 302, 495, 496, 498-539, 541-551, 554-586, 590-594, 628, 682 and 683 (C8:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions).

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NOs: 3, 8-10, 16-20, 49-51, 56-62, 64, 69-72, 74, 76-78, 80-96, 104-109, 111-115, 117, 118, 120, 121, 127, 128, 132, 133, 136-142, 148-153, 156-166, 224-226, 285-288, 297-302, 490-494, 501-514, 517-539, 541-547, 551, 554-580, 585, 586, 589-593, 628, 889-891, 899, 900, 902-916 (C10:0); or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NOs: 3, 8-10, 16-20, 49-51, 56-62, 64, 69-72, 74, 76-78, 80-96, 104-109, 111-115, 117, 118, 120, 121, 127, 128, 132, 133, 136-142, 148-153, 156-166, 224-226, 285-288, 297-302, 490-494, 501-514, 517-539, 541-547, 551, 554-580, 585, 586, 589-593, 628, 889-891, 899, 900, 902-916 (C10:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions).

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NOs: 3, 9, 10, 16-20, 49-53, 61, 62, 64, 67, 69-72, 74, 83, 85-87, 89-96, 104-113, 115, 117-122, 127, 128, 132, 133, 138, 139, 141, 142, 148-151, 153, 219, 224-226, 276, 285-288, 290-302, 487-495, 497, 501-515, 517-547, 551, 554-580, 585, 586, 588-594, 887-891, 893-916 (C12:0); or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NOs: 3, 9, 10, 16-20, 49-53, 61, 62, 64, 67, 69-72, 74, 83, 85-87, 89-96, 104-113, 115, 117-122, 127, 128, 132, 133, 138, 139, 141, 142, 148-151, 153, 219, 224-226, 276, 285-288, 290-302, 487-495, 497, 501-515, 517-547, 551, 554-580, 585, 586, 588-594, 887-891, 893-916 (C12:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions).

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NOs: 9, 10, 17-19, 34, 69, 70, 83, 85, 117, 120, 121, 127, 128, 132, 133, 139, 141, 148-151, 153, 224-226, 275, 276, 279-281, 284-302, 483-494, 497, 501-514, 517-539, 541, 543-580, 584-594, 889-892, 899, 900, 902-916 (C14:0); or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NOs: 9, 10, 17-19, 34, 69, 70, 83, 85, 117, 120, 121, 127, 128, 132, 133, 139, 141, 148-151, 153, 224-226, 275, 276, 279-281, 284-302, 483-494, 497, 501-514, 517-539, 541, 543 580, 584-594, 889-892, 899, 900, 902-916 (C14:0) by 1 to 30, such as 1 to 20, 1 to 15, 1 to 10, 1 to 5, 1 to 3 or 1 to 2 nucleotide substitutions and/or deletions (preferably substitutions).

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of altered milk fatty acid composition, within the genome of said female milk-producing cattle, said at least one polymorphism being selected from the group consisting of P #1 to P #916.

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being selected from the group consisting of P #33, P #241-P #248, P #303-P #312, P #314-P #344, P #346-P #475 and, P #477-P #481 (C16:0).

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being selected from the group consisting of P #19, P #34, P #38, P #39, P #141, P #148, P #153, P #233-P #240, P #242-P #246, P #271-P #278, P #280-P #283, P #285, P #289-P #302, P #311-P #334, P #339, P #340, P #343-P #475, P #477-P #481, P #484-P #494, P #497, P #543, P #588, P #589, P #916, P #911, P #14, P #37, P #903 and P #7 (C18:1).

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being selected from the group consisting of of P #243-P #246, P #314-P #332, P #334-P #340, P #346-P #352, P #354-P #363, P #366-P #392, P #394-P #396, P #398-P #410, P #412-P #475 and P #477-P #481 (C14:1 cis-9).

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being selected from the group consisting of P #1, P #12, P #15-P #17, P #24, P #41, P #63, P #64, P #69-P #71, P #74-P #79, P #83, P #85-P #87, P #89-P #93, P #97-P #103, P #112-P #118, P #120, P #121, P #123-P #135, P #138-P #141, P #148, P #153-P #168, P #218, P #220-P #226, P #249, P #250, P #253-P #260, P #267, P #495, P #499, P #501, P #503-P #514, P #517-P #539, P #541, P #542, P #544-P #547, P #554-P #585, P #590-P #592, P #595-P #597, P #599-P #614, P #617-P #621, P #623-P #652, P #654-P #669, P #672-P #674, P #676-P #678, P #681, P #682, P #688-P #744, P #746-P #769, P #771-P #813, P #815, P #818-P #824, P #826-P #831 and P #872 (C6:0).

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being selected from the group consisting of P #1, P #10-P #12, P #16-P #19, P #40-P #45, P #48, P #49, P #51, P #56-P #60, P #63-P #66, P #68-P #93, P #97, P #99-P #101, P #103-P #108, P #111-P #118, P #120, P #121, P #123-P #218, P #220, P #224-P #231, P #254, P #258, P #259, P #268, P #270, P #285-P #288, P #302, P #495, P #496, P #498-P #539, P #541-P #551, P #554-P #586, P #590-P #594, P #628, P #682 and P #683 (C8:0).

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being selected from the group consisting of P #3, P #8-P #10, P #16-P #20, P #49-P #51, P #56-P #62, P #64, P #69-P #72, P #74, P #76-P #78, P #80-P #96, P #104-P #109, P #111-P #115, P #117, P #118, P #120, P #121, P #127, P #128, P #132, P #133, P #136-P #142, P #148-P #153, P #156-P #166, P #224-P #226, P #285-P #288, P #297-P #302, P #490-P #494, P #501-P #514, P #517-P #539, P #541-P #547, P #551, P #554-P #580, P #585, P #586, P #589-P #593, P #628, P #889-P #891, P #899, P #900, P #902-P #916 (C10:0).

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being selected from the group consisting of P #3, P #9, P #10, P #16-P #20, P #49-P #53, P #61, P #62, P #64, P #67, P #69-P #72, P #74, P #83, P #85-P #87, P #89-P #96, P #104-P #113, P #115, P #117-P #122, P #127, P #128, P #132, P #133, P #138, P #139, P #141, P #142, P #148-P #151, P #153, P #219, P #224-P #226, P #276, P #285-P #288, P #290-P #302, P #487-P #495, P #497, P #501-P #515, P #517-P #547, P #551, P #554-P #580, P #585, P #586, P #588-P #594, P #887-P #891, P #893-P #916 (C12:0).

According to more particular embodiments, the method comprises:

determining the identity of one or more nucleotides of at least one allele, such as two, three or four alleles, of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being selected from the group consisting of P #9, P #10, P #17-P #19, P #34, P #69, P #70, P #83, P #85, P #117, P #120, P #121, P #127, P #128, P #132, P #133, P #139, P #141, P #148-P #151, P #153, P #224-P #226, P #275, P #276, P #279-P #281, P #284-P #302, P #483-P #494, P #497, P #501-P #514, P #517-P #539, P #541, P #543-P #580, P #584-P #594, P #889-P #892, P #899, P #900, P #902-P #916 (C14:0).

Having generally described this invention, a further understanding can be obtained by reference to certain specific examples, which are provided herein for purposes of illustration only, and are not intended to be limiting unless otherwise specified.

EXAMPLES Example 1: FTIR Spectroscopy and Variance Component Estimation

Estimation of Bovine Milk Fat Composition from FTIR Spectroscopy Data

Traditionally, detailed milk fat composition has been determined using gas chromatography (GC). This is an accurate but expensive method and, therefore, Fourier transform infrared spectroscopy (FTIR) has become the current standard for routine milk recording.

Liquid milk samples from Norwegian Red (NR) cattle have routinely been analyzed using an FT-IR MilkoScan Combifoss 6500 instrument (Foss, Hillerod, Denmark), and the results recorded with the Regional Laboratories of the Norwegian Herd Recording System. Samples have been homogenized and temperature regulated before entering a cuvette (37 μm) for transmission measurements in the spectral range from 925 cm-1 to 5011 cm-1. The instrument was equipped with a DTGS detector. All spectra were transformed from transmittance to absorbance units. Absorbance spectra were preprocessed by taking the second derivative using a polynomial of degree two and a window size of 9 channels followed by extended multiplicative signal correction (Martens and Stark, 1991) in order to correct for baseline variations and multiplicative effect (Zimmermann and Kohler, 2013).

Recent studies have shown that FT-IR data, calibrated against gas chromatography with flame ionization detector (GC-FID) reference data from the same samples, has the potential to give detailed prediction of milk fat composition (e. g.; Soyeurt et al., 2006; Afseth et al., 2010). An advantage of this approach is that the millions of records obtained by routine recording of cattle can be utilized to estimate genetic parameters and improve traits, such as milk fat composition, by breeding.

To obtain a calibration model for FTIR spectra, approx. 1000 samples obtained from a feeding experiment (Afseth et al., 2010) and from field sampling were analyzed in parallel by FTIR spectroscopy and GC-FID reference analysis. FTIR spectra (regressors) were subsequently calibrated against GC-FID reference values (regressands) by using Powered Partial Least Squares Regression (PPLSR, Indahl, 2005). Calibration was assessed by 20-fold cross-validation, i.e. the calibration data was divided randomly into 20 segments and each of them was used as independent test set at a time. The number of components was selected automatically by estimating if there was a significant improvement of the cross-validated prediction of the regressands when increasing the number of PLS components (linear channel combinations) in the reduced-rank PPLSR model. If improvement of the calibration model was not significant when moving from component number A to component number A-1, A was chosen as the optimal number of components. However, in order to avoid overfitting, maximum number of components was set to 25.

Subsequently, the obtained calibration model was applied to approx. 1,650,000 infrared spectra from the Regional Laboratories of the Norwegian Herd Recording System in the periods February to November 2007 and July 2008 to March 2009.

A total of 24 individual fatty acids and 12 combined traits were calibrated for in the study. Individual fatty acids included seven short- and medium-chained, even-numbered saturated FAs (C4:0, C6:0, C8:0, C10:0, C12:0, C14:0, C16:0), two long-chained saturated FAs (C18:0, C20:0), two odd-numbered saturated FAs (C15:0, C17:0), seven monounsaturated FAs (C14:1 cis-9, C16:1 cis-9, C18:1 cis-9, C18:1 cis-11, C18:1 trans-9, C18:1 trans-10, C18:1 trans-11) and six polyunsaturated FAs (C18:2 cis-9,cis-12, C18:3 cis-9,cis-12,cis-15, arachinonic acid (ARA), conjugated linoleic acid (CLA), docosahexaenoic acid (DHA) and eicosapentaenoic acid (EPA)). The combined traits were CIS (% FAs with cis bonds), TRANS (% FAs with trans bonds), TRANS:CIS (trans:cis ratio), N3 (total amount of omega-3 FAs), N6 (total amount of omega-6 FAs), N3:N6 (omega-3:omega-6 ratio), DNS (de novo FA synthesis, i.e., sum of the short-chained FAs C6:0 to C12:0), SAT (% saturated FAs), MUFA (% monounsaturated FAs), PUFA (% polyunsaturated FAs), TOTAL (total fat yield), and iodine value. NEFA (free fatty acids) and UREA were also included in the genome-wide association analyses, but these traits have built-in prediction equations in the FT-IR instrument and are stored as a routine in the Norwegian Dairy Herd Recording System as parameters of milk quality and feeding, and were therefore not calibrated for in the present study.

Estimation of Genetic Variance Components

The ˜1,650,000 FTIR-based fatty acid (FA) profile predictions for individual cattle (Y) were related to the pedigree structure of the NR population. To condense the information for genetic analyses and remove obvious outliers, a subset of the data was formed. Only FA profiles matching cattle in the herd-recording system were kept. Further, the cattle had to be in 1st to 4th lactation and the test-day between 10 and 320 days after calving. The milk yield at the test-day had to be between 5 and 50 kg, and the fat percentage between 1.75 and 7.0. Finally, the sire had to be an AI bull of NR. Milk samples were recorded on a bimonthly basis. This left 950,170 profiles from 300,126 cattle, with a pedigree of 871,455 animals.

The data was analyzed with the following mixed linear animal repeatability model:

Y=RYM _(i) +RPL _(j) +htd _(k) +pe _(l) +a _(m) +e _(ijklm),

where RYM=fixed effect of region (9 regions) by year and month of the test-day, i=1 to 170. RPL=fixed effect of region by lactation number by 10-day period in lactation of the test-day, j=1 to 1116. htd=random effect of herd by test-day, k=1 to 83,850. pe=random permanent environmental effect of the cattle on her repeated records, 1=1 to 300,126. a=random genetic effect of the animal, m=1 to 871,455. e=random residual effect.

The distributional assumptions for the random effects were htd ˜N(0,Iσ²htd), pe ˜N(0,Iσ²pe), a ˜N(0,Aσ²a) and e ˜N(0,Iσ²e), where 0 is the null vector, I the identity matrix and A is the additive genetic relationship matrix.

The variance components were estimated by the DMU software (Madsen and Jensen, 2007) using an average information algorithm. Given the variance components, breeding value and fixed effects were estimated by the DMU software using iteration on data algorithm.

Results

A key element in this study was to estimate fatty acid composition in milk samples from the nationwide recording based on FTIR spectroscopy data using a GC-FID reference analysis method [11]. The results showed that 29 of the fatty acids, that together constituted more than 90% of the total fat content, achieved cross-validated correlation coefficients above 0.5. These fatty acids where considered predictable and included in further analysis. Mean concentration of these traits from the GC-FID reference analyses as well as cross-validated correlation coefficients and heritabilities are shown in Table 3.

TABLE 3 Mean concentrations from the GC FID reference analyses, cross validated correlation coefficients (R²CV) and heritabilities for all traits. Trait Cons R²CV h² C4:0 4.16 0.73 0.353 C6:0 2.48 0.89 0.231 C8:0 1.48 0.91 0.187 C10:0 3.2 0.91 0.171 C12:0 3.55 0.91 0.179 C14:0 11.21 0.86 0.109 C14:1cis-9 0.98 0.52 0.222 C15:0 1 0.59 0.146 C16:0 25.25 0.77 0.145 C16:1cis-9 1.17 0.51 0.146 C17:0 0.49 0.43 0.142 C18:0 11.29 0.54 0.175 C18:1trans-9 0.24 0.74 0.141 C18:1trans-10 0.36 0.56 0.171 C18:1trans-11 1.33 0.67 0.092 C18:1cis-9 21.4 0.94 0.127 C18:1cis-11 0.79 0.73 0.146 C18:2cis-9, cis-12 1.39 0.61 0.172 C18:2cis-9, trans-11 0.62 0.65 0.120 C18:3cis-9, cis-12, cis-15 0.54 0.42 0.190 C20:0 0.2 0.39 0.161 ARA 0.07 0.46 0.236 EPA 0.06 0.16 0.173 DHA 0.02 0.62 0.159 SAT 64.31 0.96 0.137 MUFA 26.28 0.96 0.130 PUFA 2.7 0.72 0.171 CIS 26.43 0.96 0.138 TRANS 2.56 0.73 0.103 TRANS:CIS 0.1 0.64 0.096 DNS 10.72 0.92 0.165 N3 0.62 0.37 0.191 N6 1.47 0.62 0.170 N3:N6 0.44 0.42 0.193 TOTAL 93.29 0.59 0.106 All fatty acids are expressed as percentage by weight of total fatty acid content (on a fatty acid methyl ester basis).

Estimation of variance components showed that relatively high heritabilities were estimated from the FTIR predictions (Table 3). Heritabilities were in general higher for the shorter saturated acids than for the medium length saturated acids and the unsaturated acids.

Example 2: Genome Wide Association Study (GWAS) and Follow-Up Studies of a Region on BTA13 with Effect on De Novo Synthesized Short-Chained Fatty Acids

Daughter yield deviations (DYD) were derived from the results provided in example 1 as sire averages of daughters' predicted fatty acid compositions. Only traits with an R2CV>0.5 was included in the association study. The study was performed on 991 bulls with phenotypic and genotypic information. The average number of daughters per bull was ˜300.

Genotypes for Genome-Wide Association Analyses

Initial genotyping for the GWAS was performed on 991 Norwegian Red A.I. bulls with phenotypic information using the Affymetrix 25K bovine SNP chip (Affymetrix, Santa Clara, Calif., USA) using standard procedures. SNP filtering reduced the number of useful markers to 17,343. The markers were positioned in the genome using the UMD 3.1 assembly.

Construction of a High Density SNP Dataset with 16,679 SNPs on BTA13

Next, a dense map for fine-mapping on BTA13 was constructed by combining genotypes from the Affymetrix 25K SNP chip with genotypes from the Illumina BovineSNP50 BeadChip (54K) (Illumina, San Diego, Calif., USA) and the Illumina BovineHD Genotyping BeadChip (777K). 1575 NR bulls were genotyped for the 54K chip. 536 of these bulls were also among the 2552 genotyped for the 25K chip. Next, 384 of the 1575 bulls were genotyped for the 777K chip. The three data sets were filtered to remove SNPs with minor allele frequency <0.05 and positioned according to the UMD 3.1 assembly. The 25K dataset was imputed to 54K before the combined 54K dataset was imputed to 777K. All imputations and phasing were performed using BEAGLE v3.3.1 [18] with default options. Phase information of the imputed haplotypes were utilized to identify double recombinants and if possible correct or remove these. The resulting dataset consisted of 1024 NR bulls and 16,679 SNPs on BTA13. Average number of daughters per bull was 278. The 991 bulls used in the previous GWAS step were among these 1024 bulls.

Genome Re-Sequencing and Construction of a Sequence-Level SNP Dataset in the Candidate Gene Region

Whole-genome re-sequencing data were obtained for five NR elite bulls on an Illumina Genome Analyzer GAIIx instrument (Illumina, San Diego, Calif., USA) with 2×108 paired end reads. The five bulls were selected since they had large groups of offspring and were relatively unrelated and therefore represented the genetic diversity of the population. Library preparation was performed using a TruSeq SBS V2-GA kit (Illumina, San Diego, Calif., USA). Adaptor- and quality-trimming of raw reads in FASTQ-format was performed using the FASTX-toolkit v0.0.13 [19]. The reads were aligned against BTA13 (UMD 3.1) using Bowtie v0.12.7 [20] with default parameters. Sorting, marking of PCR duplicates and indexing of the resulting SAM files was done using Samtools v0.1.17 [21]. Between 98.7 and 99.7 percent of the reads were mapped to the bovine reference genome assembly UMD 3.1, including all chromosomes and unplaced scaffolds. Average whole genome sequence coverage for each animal was estimated using total number of sequenced fragments times read length divided by the length of the bovine genome (3 gigabases). Two bulls in the dataset had an average whole genome sequence coverage of about 10×, while three bulls had an average coverage of 4×. Variant calling was performed with Freebayes v0.1.0 [22] with a minimum read coverage of two and a minimum alternate allele count of one. The settings were chosen to maximize calling sensitivity given the relatively low sequence coverage for three of the samples.

Since the settings for the variant calling was set to detect as much variation as possible, the criteria for selecting a novel marker for further genotyping were set rather strict. A total of 1260 markers were found within the two genes NCOA6 and ACSS2 or within 2000 bp on either side of these genes. Of these, all markers in exons and UTRs were selected for genotyping together with intron SNPs that was present in the dbSNP database and co-segregated with the most significant SNP from the analyses of the high density data on BTA13. This approach resulted in 71 markers that were genotyped in 570 animals. However, as expected given the relatively relaxed SNP detection criteria applied initially, several of these markers were found to be monomorphic and hence false positives after genotyping. In total only 17 SNPs passed all steps. Of these, two exonic and 11 intronic SNPs were positioned in NCOA6, one exonic and two intronic SNPs were located in ACSS2, and one SNP was found in the neighboring gene GSS. In order to include missing genotypes, include bulls with trait data that were not genotyped, and to cover also the regions outside the two genes, the 17 novel SNPs were imputed together with SNPs from the BovineHD array positioned in the QTL region using BEAGLE v3.3.1. Hence, the final map consisted of 204 markers situated between 63,488,876 and 65,786,868 bp. Of these, 15 and 9 SNPs were located within NCOA6 and ACSS2, respectively. The total number of bulls with genotype and trait data in the dataset was 782, and the average number of daughters per son was 362. This dataset was used for fine-mapping in the candidate gene region and for haplotype analyses.

Statistical Analyses

A single marker association model was utilized for the GWAS, for the re-sequenced BTA13 map and for the candidate gene map. The analysis was performed for the 29 traits regarded predictable according to the analyses described in example 1, and on preexisting records for urea and NEFA. The model fitted to the performance information for each trait and each SNP was:

DYD _(i) =μ+b+a _(i) +e _(i)

where DYD_(i) is performance of bull i, μ is the overall mean, b is the random effect of the SNP, a_(i) is a random polygenic effect of bull i, and e_(i) is a residual effect. The DYD were weighed by the number of daughters. The genetic and residual variances were estimated from the data. The a were assumed to be from a normal distribution ˜N(0,Aσ² _(A)) where A is the relationship matrix derived from the pedigree, and σ² _(A) is the additive genetic variance. The e were assumed to be from a normal distribution ˜N(0,Wσ² _(e)) where σ² _(e) is the environmental variance.

Since the SNP was coded as a random effect, significance levels were found from the log-likelihoods (log L) of a model containing the SNP effect (Log L(H1)) as well as a model without this SNP effect (Log L(H0)), which were both calculated for each marker using the ASREML package version 2.0 [24]. A Likelihood Ratio Test-statistic (LRT) was calculated as LRT=2*(Log L(H1)−Log L(H0)). Following Baret et al. [25], the distribution of the LRT under the null hypothesis can be seen as a mixture of two chi square distributions with 0 and 1 degrees of freedom, respectively. The significance levels are then found from a chi square distribution with 1 df but doubling the probability levels. Due to the amount of multiple testing performed, we required a rather stringent significance threshold of p=0.00025. The corresponding LRT were thus found from a chi square distribution with 1 df and p=0.0005, thus the LRT must be 12.12 or higher.

Results

A total of 200 significant marker—trait associations were detected. The associations were found on 24 chromosomes and for 32 of the traits. The most interesting results were detected on BTA13, BTA1 and BTA15. P #, SEQIDNO, traits, p-values and allele substitution effects for the most relevant associations are presented in Table 4.

TABLE 4 Most significant associations (i.e., LRT > 12.12) detected by the genome-wide association analyses. Trait refers to one or more fatty acids that are significantly associated to the SNP. Effect is the effect of the SNP on the trait, i.e., the difference in concentration of the fatty acid in question between the two alleles of the SNP, measured as % by weight of total fat. P # SEQ ID NO Trait LRT Effect 1 1 C8:0 12.36 −0.00802103 C6:0 12.66 −0.0105822 2 2 DHA 13.8 0.000672764 3 3 DNS 13.04 −0.00401878 C12:0 12.51 −0.00973376 C10:0 12.93 −0.00925379 4 4 CLA 13.2 0.000416303 5 5 DHA 19.66 0.000168834 6 6 CLA 15.48 0.00575959 SAT 13.55 −0.129466 7 7 C18:1trans-9 15.8 0.0024417 8 8 C10:0 12.94 0.00463456 DNS 12.31 0.00183667 9 9 DNS 12.63 0.0010928 C14:0 15.15 −0.00184979 C12:0 13.83 −0.00486508 C10:0 14.65 −0.00279912 10 10 DNS 17.02 −0.000256256 C8:0 16.08 −0.000256256 C14:0 13.54 −0.00037812 C12:0 15.59 −0.00142054 C10:0 17.05 −0.0011639 11 11 C8:0 12.22 0.000683987 12 12 C8:0 16.74 0.00128692 C6:0 14.3 0.00477017 13 13 C4:0 18.54 0.0143173 14 14 C18:1cis-11 15.62 0.000971328 15 15 C4:0 14.44 −0.00759081 C6:0 20.66 −0.00757684 CLA 14.24 0.00262246 16 16 DNS 16.63 −0.0138831 C8:0 21.32 −0.0138831 C6:0 14.58 −0.0144535 C10:0 14.04 −0.0367898 17 17 DNS 26.24 −0.0071442 C8:0 26.98 −0.0071442 C6:0 18.76 −0.00928815 C14:0 13.16 −0.0251529 C12:0 21.97 −0.0171577 C10:0 23.69 −0.0167307 18 18 DNS 19.87 −0.00982001 C8:0 17.5 −0.00982001 C14:0 14.71 −0.0355515 C12:0 20.04 −0.0255966 C10:0 21.32 −0.0242391 19 19 C10:0 19.62 0.0124673 C12:0 23.07 0.0164781 C14:0 15.64 0.0161827 C18:1cis-9 14.06 −0.058246 C8:0 17.66 0.00356834 DNS 25.77 0.00356834 20 20 C12:0 15.74 −0.000167818 C10:0 14.86 0.000867926 21 21 C4:0 18.52 −0.0129863 22 22 C4:0 14.36 0.0169964 23 23 C4:0 12.74 0.0168102 24 24 C6:0 12.16 −0.0036454 C4:0 20.6 −0.011403 25 25 C4:0 13 −0.0181556 26 26 C4:0 14 0.0144705 27 27 C4:0 12.7 0.0295257 28 28 C4:0 13.5 0.0124391 29 29 C4:0 14.48 −0.0162925 30 30 C4:0 13.74 0.0113422 31 31 C4:0 17.6 0.031742 32 32 C4:0 12.54 0.00846089 33 33 C16:0 12.27 0.0413636 34 34 SAT 15.56 −0.0399403 MUFA 13.68 0.0342139 C18:1cis-9 14.45 0.0173785 C14:0 12.12 −0.0118568 35 35 SAT 13.14 −0.098612 36 36 NEFA 14.96 0.00103029 37 37 C18:1cis-11 13.14 −0.000169859 38 38 SAT 12.31 0.0177589 C18:1cis-9 12.18 −0.0100095 39 39 SAT 14.2 0.0109863 MUFA 13.75 −0.0181838 C18:1cis-9 13.12 −0.0193747

The most notable results were detected on BTA13, where a large number of SNPs located between 55.4 and 66.1 Mb were strongly associated to all short- and medium-chained, saturated de novo synthesized milk fatty acids (i.e.; C4:0 to C14:0 and DNS). The most significant marker was situated close to a very likely candidate gene; acyl-CoA synthetase short-chain family member 2 (ACSS2). ACSS2 is encoding an enzyme that catalyzes the activation of acetate for use in de novo synthesis of short-chained fatty acids.

The next steps therefore aimed to fine-map this region and, if possible, to identify the causal DNA variation underlying the variation in de novo synthesis. First, all traits found significant by the initial GWAS was reanalyzed for 16,679 SNPs on a high density map covering the entire length of BTA13. All significant results are shown in Table 5. The results pointed out a nearby gene, nuclear receptor coactivator 6 (NCOA6), as more significant than ACSS2. The putative role of this gene in fatty acid synthesis have so far not been investigated. However, NCOA6 is a ligand for transcription factors such as PPARy, which affects transcription of genes involved in fatty acid transport, and is proposed as a major regulator of bovine milk fat synthesis.

TABLE 5 Significant results (i.e., LRT > 12.12) from the analyses of de novo-synthesized fatty acids using a high density marker material on BTA13. Trait refers to one or more fatty acids that are significantly associated to the SNP. Effect is the effect of the SNP on the trait, i.e., the difference in concentration of the fatty acid in question between the two alleles of the SNP, measured as % by weight of total fat. P# SEQ ID NO Trait LRT Effect 40 40 C8:0 13.4 0.00188608 41 41 C6:0 13.2 0.00192254 C8:0 14.8 0.000788914 42 42 C8:0 12.4 0.000903481 43 43 C8:0 13.3 −0.000952205 44 44 C8:0 14.6 0.00246485 DNS 12.1 0.00246485 45 45 C8:0 12.8 0.00227257 46 46 C4:0 12.1 −0.00640506 15 15 C4:0 14.3 −0.00759081 C6:0 16 −0.00757684 47 47 C4:0 12.6 −0.00687608 48 48 C8:0 12.1 −0.00293636 49 49 DNS 17.5 −0.00617226 C8:0 17.5 −0.00617226 C12:0 14.4 −0.0178275 C10:0 16 −0.0160308 50 50 C12:0 15.1 −0.0135792 C10:0 12.6 −0.0103807 51 51 C10:0 13.9 −0.00996145 C12:0 14.1 −0.0113767 C8:0 12.2 −0.00374251 DNS 15.6 −0.00374251 52 52 C12:0 12.3 −0.00769547 53 53 C12:0 12.3 −0.00769547 54 54 C4:0 13.3 −0.0098508 55 55 C4:0 12.3 −0.01215 56 56 C10:0 12.8 −0.0133895 C8:0 16.4 −0.00578424 DNS 14.9 −0.00578424 57 57 DNS 15.3 −0.00578424 C8:0 16.9 −0.00578424 C10:0 13.2 −0.0133895 58 58 C10:0 12.1 −0.0125997 C8:0 15.6 −0.005502 DNS 14.1 −0.005502 59 59 DNS 14.9 −0.00578424 C8:0 16.4 −0.00578424 C10:0 12.8 −0.0133895 60 60 C10:0 12.6 −0.0133895 C8:0 16.1 −0.00578424 DNS 14.8 −0.00578424 61 61 C12:0 23.1 0.0144813 C10:0 20.1 0.0130699 62 62 C12:0 16.1 0.0141153 C10:0 13.1 0.0121343 63 63 C8:0 13.7 −0.0175384 C6:0 13.5 −0.0192056 64 64 C10:0 20.3 −0.0625506 C12:0 12.7 −0.067408 C6:0 29.7 −0.0273063 C8:0 33.4 −0.0248163 DNS 23.5 −0.0248163 65 65 C8:0 16.3 0.00773878 DNS 12.4 0.00773878 66 66 DNS 12.4 0.00773878 C8:0 16.3 0.00773878 67 67 C12:0 12.9 0.0162291 68 68 C8:0 16.3 0.00775108 DNS 12.4 0.00775108 69 69 DNS 30.2 −0.0198406 C8:0 41.7 −0.0198406 C6:0 31.1 −0.0213763 C12:0 17.8 −0.0532377 C10:0 26.5 −0.0495702 70 70 C10:0 26.5 −0.0495702 C12:0 17.8 −0.0532377 C6:0 31.1 −0.0213763 C8:0 41.7 −0.0198406 DNS 30.2 −0.0198406 71 71 DNS 16.9 −0.00905516 C8:0 18.8 −0.00905516 C6:0 12.3 −0.0115379 C12:0 12.8 −0.0203055 C10:0 16 −0.0205959 72 72 DNS 17.2 −0.00884674 C8:0 18.8 −0.00884674 C12:0 13.2 −0.019146 C10:0 16.5 −0.0197048 73 73 C8:0 17.1 −0.00840382 DNS 12.9 −0.00840382 74 74 DNS 19.1 −0.0079169 C8:0 20.3 −0.0079169 C6:0 13.8 −0.0107992 C12:0 15.1 −0.0161472 C10:0 17.2 −0.0167854 75 75 C6:0 24.3 −0.0207355 C8:0 25 −0.0179043 DNS 15.9 −0.0179043 76 76 DNS 17.1 −0.0178593 C8:0 27 −0.0178593 C6:0 24.6 −0.020456 C10:0 13.2 −0.0446094 77 77 C10:0 12.8 −0.0185742 C6:0 12.6 −0.00918383 C8:0 14.3 −0.00741921 DNS 12.7 −0.00741921 78 78 DNS 12.7 −0.00727749 C8:0 14.3 −0.00727749 C6:0 12.6 −0.0090346 C10:0 12.8 −0.0181508 79 79 C6:0 12.3 −0.00879036 C8:0 13.8 −0.00720897 80 80 C8:0 14.6 0.00414185 C10:0 13.8 0.0150976 81 81 C8:0 14.6 0.00450224 C10:0 13.8 0.0154715 82 82 C10:0 13.2 0.0154715 C8:0 14.2 0.00450224 83 83 C10:0 23.5 0.0283554 C12:0 19 0.0311255 C6:0 19.6 0.0100658 C8:0 27.8 0.0101171 DNS 22.8 0.0101171 84 84 C10:0 13.2 0.0154715 C8:0 14.2 0.00450224 85 85 DNS 22.8 0.0102997 C8:0 27.8 0.0102997 C6:0 19.6 0.0104809 C12:0 19 0.0315693 C10:0 23.5 0.0286623 86 86 C10:0 27.1 0.0217681 C12:0 27.2 0.0260882 C6:0 12.6 0.00443943 C8:0 23.1 0.00630516 DNS 24.8 0.00630516 87 87 DNS 24.8 0.00662192 C8:0 23.1 0.00662192 C6:0 12.6 0.00478141 C12:0 27.2 0.0273646 C10:0 27.1 0.0227998 88 88 C10:0 13.2 0.0154715 C8:0 14.2 0.00450224 89 89 C10:0 28 0.0222747 C12:0 27.8 0.02671 C6:0 13.4 0.0045743 C8:0 24 0.00645377 DNS 25.7 0.00645377 90 90 C10:0 28 0.0221045 C12:0 27.8 0.0264912 C6:0 13.4 0.00450331 C8:0 24 0.00639396 DNS 25.7 0.00639396 91 91 C10:0 28 0.0222226 C12:0 27.8 0.0267306 C6:0 13.4 0.00439091 C8:0 24 0.00638839 DNS 25.7 0.00638839 92 92 DNS 25.7 0.00645377 C8:0 24 0.00645377 C6:0 13.4 0.0045743 C12:0 27.8 0.02671 C10:0 28 0.0222747 93 93 C10:0 28.7 0.0222747 C12:0 28.6 0.02671 C6:0 13.8 0.0045743 C8:0 24.9 0.00645377 DNS 26.5 0.00645377 94 94 C12:0 18.6 0.0266584 C10:0 16.9 0.0221645 95 95 C10:0 16.9 0.0221645 C12:0 18.6 0.0266584 96 96 C12:0 19.6 0.0266583 C10:0 17.8 0.0221645 97 97 C8:0 16.4 0.00806355 C6:0 16.5 0.0101885 98 98 C6:0 14.3 −0.0112651 99 99 C6:0 15.1 −0.0126808 C8:0 14.2 −0.0105791 100 100 C6:0 16.5 −0.0126917 C8:0 14.3 −0.0110808 101 101 C8:0 14.3 −0.0109968 C6:0 16.5 −0.0125584 102 102 C6:0 12.1 −0.0134234 103 103 C6:0 14.4 −0.0125358 C8:0 12.8 −0.0108727 104 104 DNS 14.3 0.00787918 C8:0 14.2 0.00787918 C12:0 15 0.0278349 C10:0 13.9 0.024037 105 105 DNS 14.3 0.00787918 C8:0 14.2 0.00787918 C12:0 15 0.0278349 C10:0 13.9 0.024037 106 106 DNS 14.3 0.00787918 C8:0 14.2 0.00787918 C12:0 15 0.0278349 C10:0 13.9 0.024037 107 107 DNS 14.3 0.00787918 C8:0 14.2 0.00787918 C12:0 15 0.0278349 C10:0 13.9 0.024037 108 108 C10:0 13.9 0.024037 C12:0 15 0.0278349 C8:0 14.2 0.00787918 DNS 14.3 0.00787918 109 109 C12:0 13.9 0.0197669 C10:0 12.6 0.0177329 110 110 C12:0 13.1 0.0197669 111 111 DNS 15.5 0.00564728 C8:0 13 0.00564728 C12:0 16.1 0.0190808 C10:0 15.7 0.0168402 112 112 DNS 18.9 −0.0105537 C8:0 23.6 −0.0105537 C6:0 17.9 −0.0117802 C12:0 13.8 −0.0284888 C10:0 18.9 −0.0273379 113 113 C10:0 17.7 −0.0273379 C12:0 12.9 −0.0284888 C6:0 17.3 −0.0117802 C8:0 22.4 −0.0105537 DNS 17.7 −0.0105537 114 114 DNS 14.8 −0.0106052 C8:0 18 −0.0106052 C6:0 14.8 −0.0126255 C10:0 13.8 −0.0264331 115 115 DNS 20.2 −0.0103952 C8:0 24.4 −0.0103952 C6:0 18.3 −0.0118818 C12:0 14.9 −0.0278326 C10:0 20.3 −0.0270128 116 116 C8:0 12.1 0.00862018 C6:0 13.7 0.0121927 117 117 DNS 33.5 −0.0284217 C8:0 49.7 −0.0284217 C6:0 39 −0.0294283 C12:0 19.7 −0.0817469 C10:0 29.6 −0.0745318 118 118 C10:0 24.3 −0.0256072 C12:0 23.9 −0.030413 C6:0 16.4 −0.00703065 C8:0 26.1 −0.0083195 DNS 25.5 −0.0083195 119 119 C12:0 13.2 0.0147947 120 120 C10:0 24.2 −0.0310331 C12:0 19.7 −0.0332942 C6:0 24 −0.0146789 C8:0 31.5 −0.0122436 DNS 25.8 −0.0122436 121 121 DNS 25.8 −0.0122114 C8:0 31.5 −0.0122114 C6:0 24 −0.0146497 C12:0 19.7 −0.0330648 C10:0 24.2 −0.0309041 122 122 C12:0 13.3 0.036836 123 123 C6:0 18.7 −0.0102934 C8:0 16.7 −0.00870533 124 124 C6:0 16.1 0.0106208 C8:0 15.9 0.00682733 125 125 C8:0 15.9 0.0068272 C6:0 16.1 0.0106206 126 126 C8:0 15.9 0.0068272 C6:0 16.1 0.0106206 127 127 C10:0 12.2 −0.0271098 C6:0 16.2 −0.0118919 C8:0 20.1 −0.0106605 DNS 14.6 −0.0106605 128 128 DNS 18.1 −0.00893882 C8:0 22 −0.00893882 C6:0 16.1 −0.00997547 C12:0 12.9 −0.0256983 C10:0 15.2 −0.0232924 129 129 C8:0 13 −0.0118772 130 130 C8:0 13 −0.0118772 131 131 C8:0 13 −0.0118772 132 132 C10:0 16 −0.0383403 C6:0 25 −0.0173749 C8:0 28.6 −0.0155207 DNS 18.5 −0.0155207 133 133 C10:0 16.3 −0.0322227 C6:0 27.5 −0.0154619 C8:0 30 −0.013215 DNS 19.7 −0.013215 134 134 C8:0 13 −0.0118772 135 135 C8:0 13 −0.0118772 136 136 DNS 13.5 −0.0101673 C8:0 17.2 −0.0101673 C10:0 13 −0.0256289 137 137 DNS 13.6 −0.0101604 C8:0 17.5 −0.0101604 C10:0 13.2 −0.0254864 138 138 DNS 18.4 −0.0138838 C8:0 23.2 −0.0138838 C6:0 13.6 −0.0144543 C12:0 13.8 −0.04023 C10:0 17.7 −0.0367916 16 16 DNS 20.6 −0.0138831 C8:0 25.2 −0.0138831 C6:0 13.6 −0.0144535 C12:0 15.4 −0.040228 C10:0 19.5 −0.0367898 139 139 C10:0 23.7 0.028243 C12:0 24.5 0.0335376 C6:0 12.2 0.00718847 C8:0 24.7 0.00897561 DNS 25.8 0.00897561 140 140 DNS 21.7 −0.0119712 C8:0 33.4 −0.0119712 C6:0 27.2 −0.013484 C10:0 16.8 −0.0294542 141 141 C10:0 43.6 −0.0389109 C12:0 35.1 −0.0415682 C6:0 46.5 −0.0176825 C8:0 62.6 −0.0154576 DNS 48.8 −0.0154576 142 142 DNS 13 −0.00761768 C8:0 12.3 −0.00761768 C12:0 12.5 −0.0193179 C10:0 13 −0.0188101 143 143 DNS 12.2 −0.00711438 C8:0 14 −0.00711438 144 144 C8:0 14.5 −0.0071442 DNS 12.7 −0.0071442 145 145 C8:0 14.5 −0.0071442 DNS 12.7 −0.0071442 146 146 DNS 13.1 −0.00712916 C8:0 15 −0.00712916 17 17 DNS 12.6 −0.0071442 C8:0 14.5 −0.0071442 147 147 DNS 12.7 −0.00714426 C8:0 14.5 −0.00714426 148 148 DNS 26.4 −0.0140383 C8:0 29.6 −0.0140383 C6:0 19.7 −0.015477 C12:0 19.8 −0.0437927 C10:0 24.2 −0.0394483 149 149 C10:0 14.9 −0.0166395 C12:0 14.8 −0.0186586 150 150 C12:0 14 −0.0186586 C10:0 14.1 −0.0166395 151 151 C10:0 12.2 −0.0240498 C8:0 12.2 −0.00897534 152 152 C8:0 12.4 −0.00899286 C10:0 12.4 −0.0240665 153 153 DNS 21.7 −0.0108675 C8:0 24.1 −0.0108675 C6:0 15.6 −0.0129423 C12:0 17.5 −0.0283391 C10:0 20.5 −0.0270795 18 18 DNS 15.6 −0.00982001 C8:0 18.6 −0.00982001 C12:0 12.5 −0.0255966 C10:0 14.2 −0.0242391 154 154 C8:0 17.5 −0.0163058 C6:0 17.5 −0.0195499 155 155 C6:0 13.2 −0.00577609 C8:0 13.9 −0.00605426 156 156 C10:0 15.8 −0.0576564 C6:0 30.7 −0.0234211 C8:0 31.3 −0.0222813 DNS 19.9 −0.0222813 157 157 DNS 15 −0.0105046 C8:0 21.3 −0.0105046 C6:0 16.3 −0.0108847 C10:0 13.1 −0.0289462 158 158 C10:0 13.1 −0.0289462 C6:0 16.3 −0.0108847 C8:0 21.3 −0.0105046 DNS 15 −0.0105046 159 159 DNS 15 −0.0105046 C8:0 21.3 −0.0105046 C6:0 16.3 −0.0108847 C10:0 13.1 −0.0289462 160 160 DNS 15 −0.0105046 C8:0 21.3 −0.0105046 C6:0 16.3 −0.0108847 C10:0 13.1 −0.0289462 161 161 DNS 15 −0.0105046 C8:0 21.3 −0.0105046 C6:0 16.3 −0.0108847 C10:0 13.1 −0.0289462 162 162 C10:0 13.1 −0.0289462 C6:0 16.3 −0.0108847 C8:0 21.3 −0.0105046 DNS 15 −0.0105046 163 163 C10:0 13.1 −0.0282738 C6:0 16.3 −0.0104727 C8:0 21.3 −0.010219 DNS 15 −0.010219 164 164 DNS 18.1 −0.0222813 C8:0 29.6 −0.0222813 C6:0 30.3 −0.0234211 C10:0 13.5 −0.0576564 165 165 DNS 18.1 −0.0222813 C8:0 29.6 −0.0222813 C6:0 30.3 −0.0234211 C10:0 13.5 −0.0576564 166 166 DNS 19.9 −0.0222813 C8:0 31.3 −0.0222813 C6:0 30.7 −0.0234211 C10:0 15.8 −0.0576564 167 167 C6:0 13.5 0.00620273 C8:0 16.7 0.00722304 DNS 12.4 0.00722304 168 168 C8:0 12.9 −0.0124996 C6:0 13.3 −0.0149711 169 169 C8:0 14.8 0.0103145 170 170 DNS 12.1 0.0103145 C8:0 15.1 0.0103145 171 171 C8:0 15 0.0103951 172 172 C8:0 15 0.0103951 173 173 C8:0 15 0.0104669 174 174 C8:0 15 0.0103951 175 175 C8:0 15 0.0103282 176 176 C8:0 15 0.0103282 177 177 C8:0 15.7 0.0104445 DNS 12.3 0.0104445 178 178 C8:0 15 0.0105151 179 179 C8:0 12.1 0.0093436 180 180 C8:0 15.1 0.0102479 DNS 12.1 0.0102479 181 181 C8:0 15.2 0.0103358 DNS 12.1 0.0103358 182 182 C8:0 14.3 0.0103198 183 183 C8:0 14.2 0.0110059 184 184 C8:0 14.2 0.0110059 185 185 C8:0 14.2 0.0110059 186 186 C8:0 14.2 0.0100395 187 187 C8:0 14.2 0.0100946 188 188 C8:0 14.2 0.0100946 189 189 C8:0 14.2 0.0100946 190 190 C8:0 14.2 0.0100946 191 191 C8:0 14.2 0.0100946 192 192 C8:0 14.2 0.0101953 193 193 C8:0 14.2 0.0100946 194 194 C8:0 14.2 0.0100508 195 195 C8:0 14.2 0.0100946 196 196 C8:0 15.2 0.0099443 197 197 C8:0 14 0.0100946 198 198 C8:0 14.2 0.0102796 199 199 C8:0 14.2 0.0100946 200 200 C8:0 14.2 0.0100946 201 201 C8:0 14.2 0.0100946 202 202 C8:0 14.2 0.0102213 203 203 C8:0 14.2 0.0102215 204 204 C8:0 13.9 0.00960664 205 205 C8:0 13.9 0.00960664 206 206 C8:0 13.9 0.00973167 207 207 C8:0 12.7 0.0102215 208 208 C8:0 12.5 0.0102215 209 209 C8:0 12.1 0.0102213 210 210 C8:0 12.6 0.0102284 211 211 C8:0 12.5 0.0102201 212 212 C8:0 13.3 0.00597043 213 213 C8:0 13 0.0059564 214 214 C8:0 12.9 0.00487396 215 215 C8:0 12.9 0.00626975 216 216 C8:0 13 0.00615764 217 217 C8:0 12.6 0.00642756 218 218 C6:0 13.7 −0.0117201 C8:0 13.5 −0.0105932 219 219 C12:0 12.8 0.0163537 220 220 C6:0 15 −0.00181288 C8:0 12.1 −0.00261333 221 221 C6:0 14.7 −0.00455885 222 222 C6:0 14.7 −0.00360259 223 223 C6:0 14.7 −0.00413304

In the final step, all existing variations in a region covering NCOA6 and ACSS2 was aimed identified, and selected markers were genotyped and reanalyzed for the relevant traits. Again, the most significant associations were detected for markers within NCOA6, and none of the ACSS2 SNPs were among the 20 most significant for any of the traits. All significant results are shown in table 6.

TABLE 6 Significant results (i.e., LRT > 12.12) from the analyses of de novo-synthesized fatty acids for markers in the candidate gene region. Trait refers to one or more fatty acids that are significantly associated to the SNP. Effect is the effect of the SNP on the trait, i.e., the difference in concentration of the fatty acid in question between the two alleles of the SNP, measured as % by weight of total fat. P# SEQIDNO Trait LRT Effect 120 120 C10:0 25.12 −0.0310331 C12:0 20.66 −0.0332942 C14:0 17.96 −0.0490037 C6:0 25.02 −0.0146789 C8:0 32.08 −0.0122436 DNS 26.49 −0.0122436 121 121 C10:0 25.12 −0.0309041 C12:0 20.66 −0.0330648 C14:0 17.96 −0.0486681 C6:0 25.02 −0.0146497 C8:0 32.08 −0.0122114 DNS 26.49 −0.0122114 123 123 C6:0 17.12 −0.0102934 C8:0 17.54 −0.00870533 127 127 C10:0 16.28 −0.0271098 C12:0 12.7 −0.029506 C14:0 16.52 −0.0426528 C6:0 18.04 −0.0118919 C8:0 24.7 −0.0106605 DNS 18.52 −0.0106605 128 128 C10:0 13.12 −0.0232924 C14:0 12.12 −0.0358518 C6:0 19.22 −0.00997547 C8:0 22.36 −0.00893882 DNS 16.17 −0.00893882 129 129 C6:0 14.24 −0.0142968 C8:0 14.52 −0.0118772 130 130 C6:0 14.24 −0.0142968 C8:0 14.52 −0.0118772 131 131 C6:0 14.24 −0.0142968 C8:0 14.52 −0.0118772 132 132 C10:0 24.76 −0.0383403 C12:0 18.44 −0.0413743 C14:0 20.18 −0.0554531 C6:0 30.28 −0.0173749 C8:0 39.14 −0.0155207 DNS 26.83 −0.0155207 133 133 C10:0 19.72 −0.0322227 C12:0 14.2 −0.0348721 C14:0 20.04 −0.0477038 C6:0 30 −0.0154619 C8:0 34.1 −0.013215 DNS 22.74 −0.013215 134 134 C6:0 14.24 −0.0142968 C8:0 14.52 −0.0118772 135 135 C6:0 14.24 −0.0142968 C8:0 14.52 −0.0118772 136 136 C8:0 17.08 −0.0101673 137 137 C8:0 17.08 −0.0101604 16 16 C10:0 16.94 −0.0367898 C12:0 12.44 −0.040228 C6:0 14.28 −0.0144535 C8:0 23.64 −0.0138831 DNS 17.03 −0.0138831 139 139 C10:0 23.8 0.028243 C12:0 23.9 0.0335376 C14:0 13.6 0.0443111 C6:0 14.46 0.00718847 C8:0 26.98 0.00897561 DNS 27.01 0.00897561 140 140 C10:0 16.04 −0.0294542 C6:0 26.7 −0.013484 C8:0 31.84 −0.0119712 DNS 20.2 −0.0119712 224 224 C10:0 39.1 −0.0387091 C12:0 29.76 −0.0415053 C14:0 14.86 −0.0543235 C6:0 40.56 −0.016854 C8:0 56.9 −0.0152685 DNS 41.82 −0.0152685 225 225 C10:0 47.5 −0.0385647 C12:0 37.06 −0.0412351 C14:0 23.78 −0.0570337 C6:0 53.38 −0.0171145 C8:0 69.82 −0.0152227 DNS 52.79 −0.0152227 141 141 C10:0 45.98 −0.0389109 C12:0 35.18 −0.0415682 C14:0 22.44 −0.0579718 C6:0 53.12 −0.0176825 C8:0 68.88 −0.0154576 DNS 51.03 −0.0154576 226 226 c10:0 47.16 −0.0374487 C12:0 36.3 −0.0401502 C14:0 21.36 −0.0555947 C6:0 45.78 −0.0160816 C8:0 64.48 −0.0145849 DNS 50.24 −0.0145849 227 227 C8:0 13.18 −0.00634763 228 228 C8:0 13.16 −0.00634763 229 229 C8:0 13.88 −0.00634763 230 230 C8:0 14.52 −0.00634763 231 231 C8:0 15.1 −0.00634763 DNS 12 −0.00634763 143 143 C8:0 14.16 −0.00711438 148 148 C10:0 30.78 −0.0394483 C12:0 25.94 −0.0437927 C14:0 24.2 −0.0645359 C6:0 25.26 −0.015477 C8:0 35.36 −0.0140383 DNS 33.09 −0.0140383 149 149 C10:0 15.2 −0.0166395 C12:0 15.44 −0.0186586 C14:0 15.08 −0.0314341 C8:0 12.72 −0.0054648 DNS 15.74 −0.0054648 150 150 C10:0 15.96 −0.0166395 C12:0 16.28 −0.0186586 C14:0 16.06 −0.0314341 C8:0 13.28 −0.0054648 DNS 16.62 −0.0054648 151 151 C10:0 14.54 −0.0240498 C12:0 12.34 −0.0260339 C14:0 13.2 −0.0413449 C8:0 15.04 −0.00897534 DNS 14.97 −0.00897534 232 232 DNS 12.41 −0.00721868 152 152 C10:0 13.16 −0.0240665 C8:0 13.82 −0.00899286 DNS 13.37 −0.00899286 153 153 C10:0 24.96 −0.0270795 C12:0 20.44 −0.0283391 C14:0 21.38 −0.0458741 C6:0 21.36 −0.0129423 C8:0 31.62 −0.0108675 DNS 27.2 −0.0108675

Example 3. Genome-Wide Association Analyses Using High Density Marker Data

FTIR Spectroscopy and Variance Component Estimation

FTIR predictions and estimations of genetic variance components were performed as described in Example 1, but on a larger animal material, fewer traits and a more stringent R2CV. The calibration model was applied to 3,813,049 infrared spectra from the periods February to November 2007 and July 2008 to June 2014. A total of 28 traits were calibrated for (C4:0, C6:0, C8:0, C10:0, C12:0, C14:0, C16:0, C18:0, C20:0, C15:0, C17:0, C14:1 cis-9, C16:1 cis-9, C18:1 cis-9, C18:1 cis-11, C18:1 trans-9, C18:1 trans-10, C18:1 trans-11, C18:2 cis-9,cis-12, C18:3 cis-9,cis-12,cis-15, ARA, CLA, DHA, EPA, SAT, MUFA, PUFA, and TOTAL). The acids were considered predictable if their cross-validated correlation coefficient (R2CV) was above 0.7. Estimation of variance components was performed on 2,209,486 profiles from 426,505 cattle with a pedigree of 596,581 animals. Results are shown in Table 7.

TABLE 7 Mean concentration from the GC-FID reference analyses, cross- validated correlation coefficients (R²CV) and heritabilities (h²) for the traits with R²CV > 0.7. C4:0 is butyric acid, C6:0 is hexanoic acid, C8:0 is octanoic acid, C10:0 is decanoic acid, C12:0 is dodecanoic acid, C14:0 is tetradecanoic acid, C16:0 is hexadecenoic acid, and C18:1 is oleic acid. Trait Cons R²CV h² C4:0 4.15 0.72 0.3742 C6:0 2.48 0.87 0.2628 C8:0 1.48 0.9 0.2073 C10:0 3.2 0.9 0.1915 C12:0 3.55 0.9 0.1954 C14:0 11.22 0.85 0.1399 C16:0 25.25 0.75 0.1606 C18:1 21.4 0.94 0.1434

Genotyping

A high density SNP dataset was constructed by combining genotypes from the Affymetrix 25K SNP chip with genotypes from the Illumina BovineSNP50 BeadChip (54K) and the Illumina BovineHD Genotyping BeadChip (777K; Illumina, http://www.illumina.com). 1575 NR bulls were genotyped for the 54K chip. 536 of these bulls were also among the 2552 genotyped for the 25K chip. Next, 384 of the 1575 bulls were genotyped for the 777K chip. The three data sets were filtered to remove SNP with minor allele frequency <0.05 and positioned according to the UMD 3.1 assembly (Zimin et al., 2009). The 25K dataset was imputed to 54K before the combined 54K dataset was imputed to 777K. All imputations and phasing were performed by BEAGLE v3.3.1 (Browning and Browning, 2009). Phase information of the imputed haplotypes was utilized to identify double recombinants and correct (if possible) or remove these. The resulting dataset consisted of 1883 bulls with genotypes for 609,361 SNPs.

Statistical Analyses

A mixed linear model based single model association analysis was performed with the −mlma-loco option of the GCTA software (Yang et al., 2011). The model fitted to the performance information for each trait and each SNP was:

y=a+bx+g ⁻ +e

where y is the phenotype, a is the mean term, b is the additive effect (fixed effect) of the candidate SNP to be tested for association, x is the SNP genotype indicator variable coded as 0, 1 or 2, g is the polygenic effect (random effect) i.e. the accumulated effect of all SNPs except those on the chromosome where the candidate SNP is located, and e is the residual. For the ease of computation, the genetic variance, var(g), is estimated based on the null model i.e. y=a+g+e and then fixed while testing for the association between each SNP and the trait. The var(g−) will be re-estimated each time when a chromosome is excluded from calculating the GRM. A marker was considered significant if the −log(10) of its p-value was 5 or higher.

Results

Significant results were detected for all tested traits and most chromosomes. The most interesting results were detected on BTAS, 11, 13, 17, 19 and 27. P #, SEQIDNO, traits, p-values and allele substitution effects for the most relevant associations are presented in Table 8.

TABLE 8 Most significant associations detected by the genome-wide association analyses. Trait refers to one or more fatty acids that are significantly associated to the SNP. C4:0 is butyric acid, C6:0 is hexanoic acid, C8:0 is octanoic acid, C10:0 is decanoic acid, C12:0 is dodecanoic acid, C14:0 is tetradecanoic acid, C16:0 is hexadecanoic acid, C18:1 is oleic acid. Effect is the effect of the SNP on the trait, i.e., the difference in concentration of the fatty acid in question between the two alleles of the SNP, measured as % by weight of total fat. P# SEQIDNO Trait p-value Effect 233 233 c18:1 2.25e−07 0.124561 234 234 c18:1 8.76e−07 0.119818 235 235 c18:1 7.41e−07 0.120606 236 236 c18:1 7.41e−07 0.120606 237 237 c18:1 7.41e−07 0.120606 238 238 c18:1 4.97e−07 0.128575 239 239 c18:1 6.21e−07 0.120676 240 240 c18:1 7.23e−07 0.119724 241 241 c16:0 5.05e−11 0.160781 242 242 c18:1 7.54e−06 0.104799 c16:0 4.47e−14 0.173165 c4:0  2.4e−08 0.0202406 243 243 c4:0 5.26e−10 0.0236089 c16:0 8.65e−16 0.193433 c18:1 5.54e−07 0.122794 244 244 c4:0 5.53e−10 0.0236175 c16:0 2.22e−15 0.190968 c18:1 1.05e−06 0.119952 245 245 c18:1 3.81e−07 0.124574 c16:0 1.08e−15 0.192819 c4:0 7.03e−10 0.0234385 246 246 c4:0 3.17e−10 0.0237665 c16:0 4.63e−16 0.19409 c18:1 4.74e−07 0.122789 247 247 c16:0 7.65e−12 0.154336 248 248 c16:0 2.13e−11 0.150894 64 64 c8:0 1.34e−11 0.0229585 c10:0 8.21e−09 0.0575634 69 69 c14:0 2.66e−07 0.0759402 c12:0 6.19e−08 0.0563511 c10:0 2.93e−09 0.05246 c8:0 5.38e−12 0.0207033 c6:0 5.09e−09 0.0218123 70 70 c6:0 5.09e−09 0.0218123 c8:0 5.38e−12 0.0207033 c10:0 2.93e−09 0.05246 c12:0 6.19e−08 0.0563511 c14:0 2.66e−07 0.0759402 83 83 c14:0 1.86e−07 0.0450041 85 85 c14:0 1.86e−07 0.0450041 117 117 c14:0 4.00E−10  0.0995064 c12:0 1.67e−11 0.0755669 c10:0 4.16e−13 0.0690894 c8:0 2.87e−16 0.0264777 c6:0 1.75e−11 0.0270638 118 118 c12:0 7.46e−08 0.0331528 140 140 c6:0  2.1e−09 0.0137123 141 141 c6:0 3.14e−14 0.016716 c8:0 7.33e−17 0.0147749 c10:0 5.52e−13 0.0375993 c12:0 3.74e−11 0.0406151 c14:0 4.13e−10 0.0543995 c18:1 3.53e−06 0.11322 148 148 c18:1 1.05e−07 0.138411 c14:0 1.66e−09 0.0559529 c12:0 1.34e−09 0.0396809 c10:0 9.85e−11 0.0359642 c8:0 9.68e−13 0.0134826 c6:0 3.03e−11 0.0156058 153 153 c18:1 9.75e−06 0.10971 c14:0 7.08e−08 0.0476701 c10:0 5.77e−09 0.0308499 c8:0 2.83e−11 0.0119857 156 156 c8:0 2.03e−11 0.0217386 166 166 c10:0 6.54e−09 0.0554598 c8:0  1.4e−11 0.0219458 249 249 c6:0 8.49e−09 0.0169082 250 250 c6:0 8.49e−09 0.0169082 251 251 c4:0 6.87e−10 0.0233284 252 252 c4:0 1.52e−10 0.0324591 253 253 c6:0 1.05e−09 0.0186681 254 254 c8:0 2.57e−06 0.00798137 c6:0 7.91e−10 0.0130226 255 255 c6:0 1.06e−09 0.0130483 256 256 c6:0 4.66e−09 0.0135847 257 257 c6:0 4.66e−09 0.0135847 258 258 c6:0 1.32e−10 0.0133183 c8:0 5.04e−07 0.00834534 259 259 c6:0 8.22e−11 0.0140297 c8:0 9.72e−07 0.00847286 260 260 c6:0 8.44e−09 0.0166838 261 261 c4:0 3.83e−10 0.0305028 262 262 c4:0 2.11e−10 0.0309214 263 263 c4:0 2.02e−10 0.0310054 264 264 c4:0 3.03e−10 0.0306546 265 265 c4:0 2.11e−10 0.0309214 266 266 c4:0 3.83e−10 0.0305028 267 267 c6:0 7.16e−09 0.01595 c4:0 1.11e−10 0.0306284 268 268 c8:0 2.07e−06 0.00800641 269 269 c4:0 1.42e−10 0.0425918 270 270 c8:0 3.56e−07 0.00937742 271 271 c18:1 3.21e−08 0.132082 272 272 c18:1 3.21e−08 0.132082 273 273 c18:1 3.21e−08 0.132082 274 274 c18:1 1.19e−07 0.16861 275 275 c14:0 1.39e−08 0.0605594 c18:1 5.84e−09 0.174364 276 276 c12:0 4.09e−07 0.0380963 c14:0 2.42e−09 0.0638052 c18:1 1.48e−09 0.181465 277 277 c18:1 7.63e−07 0.155925 278 278 c18:1 4.36e−07 0.160184 279 279 c14:0 8.43e−08 0.0757869 280 280 c14:0 6.84e−08 0.0763375 c18:1 5.41e−07 0.198993 281 281 c18:1  5.8e−07 0.198818 c14:0 5.73e−08 0.0769278 282 282 c18:1 9.82e−07 0.193985 283 283 c18:1 9.82e−07 0.193985 284 284 c14:0 5.64e−08 0.077563 285 285 c8:0 6.61e−07 0.0134962 c10:0 1.46e−08 0.0453257 c12:0 1.46e−08 0.053392 c14:0 1.66e−10 0.0855873 c18:1 1.58e−08 0.212481 286 286 c8:0  8.5e−07 0.0166128 c10:0 7.58e−08 0.0534673 cl2:0 1.21e−07 0.0619985 c14:0 2.32e−08 0.0930236 287 287 c8:0 5.75e−07 0.0168623 c10:0 4.09e−08 0.0545418 c12:0  6.4e−08 0.063328 c14:0 1.19e−08 0.0948983 288 288 c8:0 5.93e−08 0.0205638 c10:0 1.59e−09 0.0674685 c12:0 2.46e−09 0.0785509 c14:0 2.48e−10 0.118462 289 289 c14:0 9.81e−09 0.0494494 c18:1 1.16e−06 0.117704 290 290 c18:1 1.16e−06 0.117704 c14:0 9.81e−09 0.0494494 291 291 c14:0 9.81e−09 0.0494494 c18:1 1.16e−06 0.117704 292 292 c18:1 1.16e−06 0.117704 c14:0 9.81e−09 0.0494494 293 293 c14:0 9.81e−09 0.0494494 c18:1 1.16e−06 0.117704 294 294 c14:0 9.81e−09 0.0494494 c18:1 1.16e−06 0.117704 295 295 c18:1 1.16e−06 0.117704 c14:0 9.81e−09 0.0494494 296 296 c18:1 1.16e−06 0.117704 c14:0 9.81e−09 0.0494494 297 297 c10:0 2.29e−07 0.0267072 c12:0 6.69e−08 0.0328482 c14:0 3.61e−09 0.0509863 c18:1  6.4e−07 0.120731 298 298 c18:1  6.4e−07 0.120731 c14:0 3.61e−09 0.0509863 c12:0 6.69e−08 0.0328482 c10:0 2.29e−07 0.0267072 299 299 c18:1  6.4e−07 0.120731 c14:0 3.61e−09 0.0509863 c12:0 6.69e−08 0.0328482 c10:0 2.29e−07 0.0267072 300 300 c18:1  6.4e−07 0.120731 c14:0 3.61e−09 0.0509863 c12:0 6.69e−08 0.0328482 c10:0 2.29e−07 0.0267072 301 301 c18:1 5.82e−07 0.121087 c14:0 3.89e−09 0.0508402 c12:0 7.81e−08 0.0326544 c10:0 2.73e−07 0.0265195 302 302 c8:0 4.19e−06 0.0183894 c10:0 8.86e−10 0.0722146 c12:0 3.11e−10 0.0874091 c14:0 3.29e−11 0.130797 c18:1 6.26e−07 0.275795 303 303 c16:0 3.79e−11 0.204002 304 304 c16:0 6.38e−08 0.129454 305 305 c16:0 5.04e−08 0.135218 306 306 c16:0 5.91e−08 0.134387 307 307 c16:0 4.74e−08 0.135212 308 308 c16:0 3.74e−08 0.136219 309 309 c16:0 7.71e−08 0.13307 310 310 c16:0 3.74e−08 0.136219

Example 4. Association Analyses Using Sequence-Level Markers in Selected Genomic Regions

The final step was to re-analyze the most significant regions detected in Example 3 using sequence-level variants on BTA11, 13, 17 and 19. Trait data was found as described in Example 3.

Whole-Genome Sequencing and Imputation

168 animals of the Norwegian Red cattle breed where sequenced. Sequencing was performed by the Norwegian Sequencing Centre, Oslo, Norway using a HiSeq 2500 platform according to the manufacturer's protocols. Samples were prepared for paired-end sequencing (2×125 bp) using TruSeq DNA PCR-free library preparation kits and sequenced with the manufacturers V4 kit (Illumina, San Diego, Calif., USA) to generate an average of 9×coverage. Sequence data from 21 Norwegian Red bulls used for artificial insemination were also available from another project (Olsen et al., unpublished). All reads were aligned against the bovine reference genome UMD 3.1, using BWA-mein version 0.7.10 (Li, 2013). Variant calling was done with FreeBayes version 1.0.2 (Garrison & Marth, 2012). Genotypes of the called variants were refined and phased using Beagle version 4.1 (Browning & Browning, 2009). The resulting phased dataset was then used as a reference panel for imputing 1816 animals to full sequence, also using Beagle 4.1.

Statistical Analyses

Association analyses were performed with the ASREML package version 2.0 (Gilmour et al., 2006). The model that was fitted to the information on performance for each trait—marker combination was:

DYD=1μXb+Za+e,

where DYD is the vector of bull performances weighed by the number of daughters, 1 is a vector of ones, μ is the overall mean, X is a vector of SNP genotypes coded as 0, 1, or 2 depending on the number of copies of the first allele, b is the fixed effect of the marker, Z is an incidence matrix relating phenotypes to the corresponding random polygenic effects, a is a vector of random polygenic effects, and e is a vector of residual effects. Genetic and residual variances were estimated from the data. a was assumed to follow a normal distribution ˜N(0,Aσ_(A) ²) where A is the relationship matrix derived from the pedigree, and σ_(A) ² is the additive genetic variance. e was assumed to follow a normal distribution ˜N(0, Io_(e) ²) where σ_(e) ² is the residual variance. Association analysis was performed for each individual marker, and then the p-value for the marker effect was calculated with the R function pf( ).

Results

For all tested chromosomes (i.e., BTA11, 13, 17 and 19), highly significant associations were detected close to or within known candidate genes. P #, SEQIDNO, traits, p-values and allele substitution effects for the most relevant associations are presented in Table 9.

TABLE 9 Significant associations detected by the genome-wide association analyses. Trait refers to one or more fatty acids that are significantly associated to the polymorphism. Effect is the effect of the polymorphism on the trait, i.e., the difference in concentration of the fatty acid in question between the two alleles of the polymorphism, measured as % by weight of total fat. P# SEQIDNO Trait P-value Effect 117 117 C8:0  2.3014830551197799E−16 0.02815 C10:0  5.8976455450284501E−13 0.0732 C12:0  2.5389592799163501E−11 0.08002 C14:0  3.7247485266275898E−11 0.1121 141 141 C6:0  1.3070524624908399E−15 0.01795 C8:0  8.0096072416566797E−18 0.01557 C10:0  1.1989284537494899E−13 0.03978 C12:0  1.8801231438726598E−11 0.04251 C14:0  9.7948456090688495E−12 0.06081 148 148 C12:0   3.03855288409611E−11 0.04825 C14:0  5.2870202455405602E−12 0.0705 C18:1cis-9  1.66685761535244E−8 0.1643 224 224 C6:0   1.67177926214398E−15 0.01803 C8:0  7.4456438235387396E−18 0.01571 C10:0  1.4255384497315401E−13 0.03999 C12:0  2.2163898231281201E−11 0.04272 C14:0  4.7503119381623603E−11 0.05927 225 225 C6:0  6.8224346074786399E−16 0.01826 C8:0  7.2315971463352595E−18 0.01569 C10:0  1.5887627833528101E−13 0.03986 C12:0  2.8573276932427101E−11 0.04243 C14:0  1.2010385440067199E−11 0.06098 226 226 C6:0  5.1094854026620902E−15 0.0174 C8:0   1.86730902209013E−17 0.01524 C10:0   1.01891692801114E−13 0.0395 C12:0  1.4659211231729599E−11 0.04232 C14:0  3.6985796833596601E−12 0.06142 242 242 C4:0  1.2928384351839337e−7 0.02075 C16:0   2.2630269905553917e−12 0.1758 C18:1cis-9   4.756542897324087e−6 0.1174 243 243 C4:0  1.8152184244684335e−8 0.02268 C16:0   5.095336086824539e−13 0.1856 C14:1cis-9   1.7203708485289344e−32 0.01703 C18:1cis-9   7.531875593020596e−6 0.118 244 244 C4:0  2.8772158824693984e−8 0.02246 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9  2.1968947070395785e−6 0.1252 245 245 C4:0  2.8772158824693984e−8 0.02246 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9  2.1968947070395785e−6 0.1252 246 246 C4:0   3.011420785499756e−8 0.02242 C16:0   3.901378661041524e−13 0.1872 C14:1cis-9   8.701149888615851e−32 0.01691 C18:1cis-9  2.5899127171794412e−6 0.1243 247 247 C4:0  4.6019784418698985e−7 0.01905 290 290 C12:0 5.0351573929741803E−6 0.02967 291 291 C12:0 5.5255980595812297E−6 0.02931 C14:0 8.8207972109658898E−7 0.04464 292 292 C12:0 7.9329768149947606E−6 0.02904 293 293 C12:0 7.9329768149947606E−6 0.02904 294 294 C12:0 7.9329768149947606E−6 0.02904 295 295 C12:0 7.9329768149947606E−6 0.02904 296 296 C12:0 5.7884041878071203E−6 0.02925 C14:0 9.1428382189332197E−7 0.04458 302 302 C10:0 1.4385618706753499E−8 0.06922 C12:0  1.09508753457544E−8 0.08223 C14:0  1.07501268719868E−9 0.1236 311 311 C4:0  1.5137820662783228e−7 0.02128 C16:0   2.437824562717747e−12 0.1811 C18:1cis-9  2.7266827435303454e−6 0.1242 312 312 C4:0  1.5137820662783228e−7 0.02128 C16:0   2.437824562717747e−12 0.1811 C18:1cis-9  2.7266827435303454e−6 0.1242 313 313 C4:0  2.1294923450168264e−7 0.02045 C18:1cis-9   7.650150055787524e−6 0.1152 314 314 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 315 315 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 316 316 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 317 317 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 318 318 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 319 319 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 320 320 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 321 321 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 322 322 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 323 323 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 324 324 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 325 325 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 326 326 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 327 327 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 328 328 C4:0   7.278974349272435e−8 0.02197 C16:0   1.734970266060783e−13 0.1916 C14:1cis-9   2.4769509682289905e−31 0.01693 C18:1cis-9  1.2109416972909078e−6 0.1294 329 329 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 330 330 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 331 331 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 332 332 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 333 333 C16:0   8.114314687461337e−13 0.1872 C18:1cis-9   9.714062226470646e−7 0.1312 334 334 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 335 335 C4:0  1.5767373661220744e−7 0.0221 C16:0   6.3553468887018205e−12 0.1847 C14:1cis-9   1.1235150399561972e−30 0.01729 336 336 C4:0  1.5767373661220744e−7 0.0221 C16:0   6.3553468887018205e−12 0.1847 C14:1cis-9   1.1235150399561972e−30 0.01729 337 337 C4:0  1.5767373661220744e−7 0.0221 C16:0   6.3553468887018205e−12 0.1847 C14:1cis-9   1.1235150399561972e−30 0.01729 338 338 C4:0   1.353447649674352e−7 0.02223 C16:0   5.811599778385854e−12 0.1851 C14:1cis-9   1.4735867085928354e−30 0.01726 339 339 C4:0   4.494458973358419e−8 0.02271 C16:0   8.399593306089093e−13 0.1894 C14:1cis-9   6.771136889228095e−32 0.01738 C18:1cis-9   8.750764458845112e−6 0.1206 340 340 C4:0  1.7636328224756067e−7 0.02149 C16:0   7.645371862105105e−13 0.188 C14:1cis-9   5.0024549398183224e−30 0.0167 C18:1cis-9  2.7548250183340124e−6 0.126 341 341 C4:0   7.442792433548095e−7 0.02062 C16:0   3.2852640568732234e−12 0.185 342 342 C4:0   7.71434569875298e−7 0.02059 C16:0   3.3179747247742437e−12 0.1849 343 343 C4:0   9.721829816678287e−7 0.0198 C16:0   6.103136316054401e−13 0.1854 C18:1cis-9   9.888231648289864e−7 0.1291 344 344 C16:0   4.192896736223586e−13 0.1874 C18:1cis-9   1.241649214752762e−6 0.1284 345 345 C18:1cis-9   9.485667292863972e−6 0.1367 346 346 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 347 347 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 348 348 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 349 349 C4:0   7.205410314354753e−8 0.02199 C16:0   2.403578558716973e−13 0.1906 C14:1cis-9   2.7451035248502325e−31 0.01693 C18:1cis-9   1.255213977040492e−6 0.1293 350 350 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 351 351 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 352 352 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 353 353 C4:0   7.143926265738729e−7 0.02011 C16:0   6.493404779341801e−13 0.1858 C18:1cis-9  3.4731332592943718e−6 0.1229 354 354 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 55 355 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 356 356 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 357 357 C4:0   6.443792098934717e−8 0.02207 C16:0   2.5253095891876994e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 358 358 C4:0  3.3665599590093695e−8 0.0224 C16:0   2.231812198071488e−13 0.1897 C14:1cis-9   6.113418920441182e−32 0.017 C18:1cis-9   2.195605222243276e−7 0.1373 359 359 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 360 360 C4:0   7.132640516922274e−8 0.02184 C16:0   1.3094322833208976e−13 0.1913 C14:1cis-9   1.8730971384864796e−31 0.01684 C18:1cis-9  4.0199932688293885e−8 0.1452 361 361 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 362 362 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 363 363 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 364 364 C4:0   8.812704304509378e−7 0.02024 C16:0   6.066803065128827e−14 0.1967 C18:1cis-9   7.144032066720917e−7 0.1332 365 365 C4:0   7.995573787063973e−7 0.02032 C16:0   7.839591476556987e−14 0.1959 C18:1cis-9   8.036775888619343e−7 0.1326 366 366 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 367 367 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 368 368 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 369 369 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 370 370 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 371 371 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 372 372 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 373 373 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 374 374 C4:0   6.346390796548164e−8 0.02209 C16:0   2.500479056866569e−13 0.1905 C14:1cis-9   2.7968934535856455e−31 0.01693 C18:1cis-9  1.2297178880669441e−6 0.1294 375 375 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 376 376 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 377 377 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 378 378 C4:0   6.346390796548164e−8 0.02209 C16:0   2.500479056866569e−13 0.1905 C14:1cis-9   2.7968934535856455e−31 0.01693 C18:1cis-9  1.2297178880669441e−6 0.1294 379 379 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 380 380 C4:0   6.346390796548164e−8 0.02209 C16:0   2.500479056866569e−13 0.1905 C14:1cis-9   2.7968934535856455e−31 0.01693 C18:1cis-9  1.2297178880669441e−6 0.1294 381 381 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 382 382 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 383 383 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 384 384 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 385 385 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 386 386 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 387 387 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 388 388 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 389 389 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 390 390 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 391 391 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 392 392 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 393 393 C4:0  2.1559811336931593e−8 0.02249 C16:0   9.942389518170167e−13 0.1827 C18:1cis-9  1.9926107976021747e−6 0.1248 394 394 C4:0   3.577620016917801e−8 0.02231 C16:0   1.1865936126672857e−13 0.1914 C14:1cis-9   1.3072036972397023e−30 0.0166 C18:1cis-9   7.254826833945297e−7 0.131 395 395 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 396 396 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 397 397 C4:0  1.4313954046104633e−7 0.02177 C16:0   1.0332931244476925e−13 0.196 C18:1cis-9   9.516673708273554e−7 0.1324 398 398 C4:0  1.1384816126435856e−7 0.02191 C16:0   5.6064937335358955e−14 0.1978 C14:1cis-9   1.5533049883745766e−30 0.01691 C18:1cis-9   5.071147162114983e−7 0.1355 399 399 C4:0   5.365050090229759e−7 0.02021 C16:0   1.391247960614076e−13 0.1899 C14:1cis-9   9.675984237123455e−32 0.01684 C18:1cis-9  1.8643345505033625e−6 0.1254 400 400 C4:0   8.139698937794954e−8 0.02191 C16:0   2.439412688304182e−13 0.1907 C14:1cis-9   2.5847556040758126e−31 0.01694 C18:1cis-9  1.1155508871296394e−6 0.13 401 401 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 402 402 C4:0  1.3743120059032624e−7 0.02143 C16:0    9.79468415499461e−14 0.1929 C14:1cis-9   1.5105995593840388e−30 0.01667 C18:1cis-9  2.2428579889633397e−6 0.1257 403 403 C4:0  1.3743120059032624e−7 0.02143 C16:0    9.79468415499461e−14 0.1929 C14:1cis-9   1.5105995593840388e−30 0.01667 C18:1cis-9  2.2428579889633397e−6 0.1257 404 404 C4:0   6.443792098934717e−8 0.02208 C16:0   2.475893088729249e−13 0.1905 C14:1cis-9   2.8492685771524566e−31 0.01693 C18:1cis-9  1.2424030932700843e−6 0.1293 405 405 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 406 406 C4:0  1.8184395005057115e−7 0.0215 C16:0   8.574332970891014e−14 0.1958 C14:1cis-9   1.9635728823887853e−30 0.01685 C18:1cis-9  1.9623263053383544e−6 0.128 407 407 C4:0  1.7344347301554467e−8 0.02279 C16:0    2.34482969221407e−13 0.1889 C14:1cis-9   3.206335307398801e−31 0.01674 C18:1cis-9   8.24504574505618e−7 0.1302 408 408 C4:0   1.769883723743664e−8 0.02276 C16:0   2.2651322023310465e−13 0.1889 C14:1cis-9   3.297514139655115e−31 0.01673 C18:1cis-9   8.20293094909458e−7 0.1302 409 409 C4:0   9.625863506374483e−8 0.02201 C16:0   4.1396971873752493e−13 0.1907 C14:1cis-9   2.571995323610433e−31 0.01711 C18:1cis-9   2.04434028213731e−6 0.128 410 410 C4:0   9.432119242564688e−8 0.02202 C16:0   3.4647234925139456e−13 0.1913 C14:1cis-9   2.6950184884574883e−31 0.01711 C18:1cis-9  1.7433347196914435e−6 0.1289 411 411 C4:0   8.306762983283962e−8 0.02188 C16:0    2.36832509070101e−13 0.1906 C18:1cis-9   1.132858006469425e−6 0.1297 412 412 C4:0  1.7878797515737317e−8 0.02281 C16:0   2.7060583938165915e−13 0.1887 C14:1cis-9   2.8130986201265264e−31 0.01679 C18:1cis-9  1.0120206967655212e−6 0.1294 413 413 C4:0  1.7878797515737317e−8 0.02281 C16:0   2.7060583938165915e−13 0.1887 C14:1cis-9   2.8130986201265264e−31 0.01679 C18:1cis-9  1.0120206967655212e−6 0.1294 414 414 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 415 415 C4:0  4.6805407049219326e−8 0.02223 C16:0   4.098958348828484e−13 0.1881 C14:1cis-9    3.19491320822314e−32 0.01712 C18:1cis-9  3.1983961715065176e−6 0.1238 416 416 C4:0   4.75230955988751e−8 0.02225 C16:0   3.676483332686772e−13 0.1888 C14:1cis-9   3.813440085778458e−32 0.01713 C18:1cis-9   2.75484697268075e−6 0.1248 417 417 C4:0  1.1634008599491163e−8 0.02304 C16:0   1.0762761292334859e−12 0.1835 C14:1cis-9   9.283687196248366e−31 0.01661 C18:1cis-9   1.261783342372347e−6 0.1279 418 418 C4:0  1.1634008599491163e−8 0.02283 C16:0   5.329125986254982e−13 0.1842 C14:1cis-9    7.1437372441913e−31 0.01649 C18:1cis-9   4.229600405536392e−8 0.1432 419 419 C4:0  3.4669246927481577e−9 0.02373 C16:0   3.0637351462276833e−12 0.1789 C14:1cis-9   2.650905951040827e−31 0.01668 C18:1cis-9  1.1804042528860565e−6 0.1276 420 420 C4:0   7.348018678688381e−9 0.02326 C16:0    9.7471771406907e−13 0.1831 C14:1cis-9   8.376623785752058e−31 0.01656 C18:1cis-9  1.3539395131267877e−8 0.1491 421 421 C4:0   6.189854495279285e−9 0.02355 C16:0   2.4025426097180356e−12 0.1812 C14:1cis-9   1.3753815674381856e−30 0.01662 C18:1cis-9  4.7214763557842583e−7 0.1334 422 422 C4:0  6.0662758585827845e−9 0.02358 C16:0   3.048682564573627e−12 0.1805 C14:1cis-9   3.0354445535356497e−30 0.01654 C18:1cis-9   6.684979946696033e−7 0.1317 423 423 C4:0   4.999606867873136e−8 0.02225 C16:0   2.488155653647394e−13 0.1904 C14:1cis-9   6.339440522103002e−32 0.0171 C18:1cis-9   1.07072951258652e−6 0.1301 424 424 C4:0   3.860214491652213e−8 0.02242 C16:0   3.185474007525172e−13 0.1894 C14:1cis-9   5.163345070037479e−32 0.01711 C18:1cis-9  1.1212902389279808e−6 0.1297 425 425 C4:0  3.3836124043964913e−8 0.0225 C16:0   3.7314190059794324e−13 0.1888 C14:1cis-9   4.815234483620888e−32 0.0171 C18:1cis-9   1.16824218168249e−6 0.1294 426 426 C4:0  4.6805407049219326e−8 0.02229 C16:0   2.6012349668551466e−13 0.1903 C14:1cis-9   6.135801782045503e−32 0.0171 C18:1cis-9   1.07072951258652e−6 0.13 427 427 C4:0   3.999663694839671e−8 0.02241 C16:0   2.8291852447940065e−13 0.19 C14:1cis-9   1.641110214369391e−32 0.01726 C18:1cis-9  1.6391420527725762e−6 0.1278 428 428 C4:0  4.9743070974814015e−8 0.02225 C16:0   2.439412688304182e−13 0.1905 C14:1cis-9   6.339440522103002e−32 0.0171 C18:1cis-9  1.0652548554351088e−6 0.1301 429 429 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 430 430 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 431 431 C4:0   6.346390796548164e−8 0.02209 C16:0   2.653216867291837e−13 0.1903 C14:1cis-9   2.783854972863858e−31 0.01693 C18:1cis-9  1.2360413508923763e−6 0.1293 432 432 C4:0   5.233192492552268e−8 0.02213 C16:0    9.50244078190953e−14 0.1929 C14:1cis-9   8.996521334901145e−33 0.01726 C18:1cis-9   6.82250700871394e−7 0.1319 433 433 C4:0   5.050594250300961e−8 0.02216 C16:0   9.316797075465843e−14 0.193 C14:1cis-9    9.33776713381136e−33 0.01726 C18:1cis-9   6.787683291596898e−7 0.1319 434 434 C4:0   5.233192492552268e−8 0.02213 C16:0    9.50244078190953e−14 0.1929 C14:1cis-9   8.996521334901145e−33 0.01726 C18:1cis-9   6.82250700871394e−7 0.1319 435 435 C4:0   5.233192492552268e−8 0.02213 C16:0    9.50244078190953e−14 0.1929 C14:1cis-9   8.996521334901145e−33 0.01726 C18:1cis-9   6.82250700871394e−7 0.1319 436 436 C4:0   6.443792098934717e−8 0.02207 C16:0   2.512863600755294e−13 0.1905 C14:1cis-9   2.7319294110163084e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 437 437 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 438 438 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 439 439 C4:0   6.476591276091663e−8 0.02207 C16:0   2.5378173275509097e−13 0.1904 C14:1cis-9   2.7447244560589406e−31 0.01693 C18:1cis-9  1.2360469599051865e−6 0.1293 440 440 C4:0  2.8772158824693984e−8 0.02246 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9  2.1968947070395785e−6 0.1252 441 441 C4:0   6.779423288772559e−8 0.02183 C16:0   3.6227528835872935e−13 0.1874 C14:1cis-9   6.3324542156145576e−31 0.01667 C18:1cis-9  1.4792508710959468e−6 0.1272 442 442 C4:0  2.8772158824693984e−8 0.02246 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9  2.1968947070395785e−6 0.1252 443 443 C4:0  2.8772158824693984e−8 0.02246 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9  2.1968947070395785e−6 0.1252 444 444 C4:0  2.8772158824693984e−8 0.02246 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9  2.1968947070395785e−6 0.1252 445 445 C4:0  2.8772158824693984e−8 0.02246 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9  2.1968947070395785e−6 0.1252 446 446 C4:0  2.8772158824693984e−8 0.02246 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9  2.1968947070395785e−6 0.1252 447 447 C4:0   3.249192944267236e−8 0.02236 C16:0   3.297692175654934e−13 0.1878 C14:1cis-9   1.5967584472209152e−31 0.01684 C18:1cis-9  2.8121560494414533e−6 0.1238 448 448 C4:0   3.249192944267236e−8 0.02236 C16:0   3.297692175654934e−13 0.1878 C14:1cis-9   1.5967584472209152e−31 0.01684 C18:1cis-9  2.8121560494414533e−6 0.1238 449 449 C4:0  1.0357668021584458e−8 0.02278 C16:0   1.4886947039786878e−13 0.1875 C14:1cis-9   1.8659338846662636e−31 0.01655 C18:1cis-9   8.563916602878727e−8 0.1392 450 450 C4:0   3.523609489908919e−8 0.02229 C16:0   3.169907723250786e−13 0.1878 C14:1cis-9   2.5347927796226416e−31 0.01677 C18:1cis-9   2.826677856104394e−6 0.1237 451 451 C4:0  2.8772158824693984e−8 0.02246 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9  2.1968947070395785e−6 0.1252 452 452 C4:0   2.891826347380931e−8 0.02245 C16:0   2.7061789219454134e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9   2.174421685370506e−6 0.1252 453 453 C4:0  2.8772158824693984e−8 0.02246 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9  2.1968947070395785e−6 0.1252 454 454 C4:0   3.595771825173331e−8 0.02231 C16:0   1.309462987689054e−13 0.1912 C14:1cis-9   3.719509922115289e−31 0.01675 C18:1cis-9   3.771598489537187e−6 0.1223 455 455 C4:0   3.595771825173331e−8 0.02231 C16:0   1.309462987689054e−13 0.1912 C14:1cis-9   3.719509922115289e−31 0.01675 C18:1cis-9   3.771598489537187e−6 0.1223 456 456 C4:0  2.1342350383768972e−8 0.02262 C16:0   1.5874008557626008e−13 0.1901 C14:1cis-9   1.9889611657374917e−31 0.01679 C18:1cis-9  1.6731590847585173e−6 0.1264 457 457 C4:0   2.123461373479123e−8 0.02263 C16:0   1.564064291826473e−13 0.1901 C14:1cis-9   2.0076282248558306e−31 0.01679 C18:1cis-9  1.6645889394847738e−6 0.1264 458 458 C4:0  4.1441656818356155e−8 0.02204 C16:0   1.3452000582278674e−14 0.1971 C14:1cis-9   4.658577156152001e−32 0.01687 C18:1cis-9  1.0875609059743566e−7 0.1393 459 459 C4:0  4.1441656818356155e−8 0.02204 C16:0   1.3452000582278674e−14 0.1971 C14:1cis-9   4.658577156152001e−32 0.01687 C18:1cis-9  1.0875609059743566e−7 0.1393 460 460 C4:0  2.9065112163706328e−8 0.02253 C16:0   9.643870137669794e−14 0.1928 C14:1cis-9   6.468699750053031e−30 0.01646 C18:1cis-9   3.439605203642688e−7 0.1352 461 461 C4:0  2.8772158824693984e−8 0.02246 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9  2.1968947070395785e−6 0.1252 462 462 C4:0  2.9810649930934736e−8 0.02243 C16:0   4.525190120362981e−13 0.1868 C14:1cis-9   1.4478237941937539e−31 0.01686 C18:1cis-9  3.1656254410155834e−6 0.1233 463 463 C4:0  2.8772158824693984e−8 0.02246 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9  2.1968947070395785e−6 0.1252 464 464 C4:0  3.8212749674616415e−8 0.02236 C16:0   9.982923596453529e−14 0.1929 C14:1cis-9   4.0653359243903524e−30 0.01654 C18:1cis-9   3.13772277624039e−7 0.1358 465 465 C4:0   2.891826347380931e−8 0.02246 C16:0   2.588471941432331e−13 0.1887 C14:1cis-9   1.3687458227832632e−31 0.01687 C18:1cis-9  2.1521795116735227e−6 0.1253 466 466 C4:0   6.00171654737797e−8 0.02189 C16:0   1.4814330923969496e−13 0.1902 C14:1cis-9   4.046571109259362e−31 0.0167 C18:1cis-9   1.622394823542191e−6 0.1265 467 467 C4:0   4.186466514671147e−8 0.02202 C16:0    4.1807514204675e−13 0.1857 C14:1cis-9   1.011834685681615e−31 0.01677 C18:1cis-9  5.4676200339773355e−6 0.1193 468 468 C4:0  2.8772158824693984e−8 0.02246 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9  2.1968947070395785e−6 0.1252 469 469 C4:0  2.8772158824693984e−8 0.02246 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9  2.1968947070395785e−6 0.1252 470 470 C4:0  2.8772158824693984e−8 0.02246 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9  2.1968947070395785e−6 0.1252 471 471 C4:0  2.8772158824693984e−8 0.02246 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9  2.1968947070395785e−6 0.1252 472 472 C4:0  2.4467903856632792e−8 0.02268 C16:0   5.095552826280808e−13 0.1873 C14:1cis-9   1.5676510406490099e−31 0.01693 C18:1cis-9  1.7344036212755845e−6 0.1271 473 473 C4:0  2.8772158824693984e−8 0.02246 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9  2.1968947070395785e−6 0.1252 474 474 C4:0  2.8772158824693984e−8 0.02246 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9  2.1968947070395785e−6 0.1252 475 475 C4:0  2.8772158824693984e−8 0.02245 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9   2.185629190341092e−6 0.1252 476 476 C4:0   7.44290206536497e−7 0.01877 477 477 C4:0  2.8772158824693984e−8 0.02245 C16:0   2.692839941936475e−13 0.1886 C14:1cis-9   1.3124265867869915e−31 0.01687 C18:1cis-9   2.185629190341092e−6 0.1252 478 478 C4:0  1.2677140785248468e−8 0.02289 C16:0   2.653157694797189e−13 0.1876 C14:1cis-9   4.317494454151923e−33 0.01717 C18:1cis-9  1.5333022239870944e−6 0.1264 479 479 C4:0  1.7973821612500078e−8 0.02258 C16:0   3.4547738903348437e−13 0.186 C14:1cis-9   1.541015639769122e−32 0.01698 C18:1cis-9   4.035230831530114e−6 0.1208 480 480 C4:0  2.8773914333859296e−8 0.02214 C16:0   6.152748171738368e−13 0.1831 C14:1cis-9   3.4592948055240004e−33 0.01705 C18:1cis-9   7.810598625171563e−6 0.1165 481 481 C4:0  1.9782323131435696e−8 0.02265 C16:0   4.306749252971704e−13 0.1864 C14:1cis-9    1.86100369806756e−32 0.01705 C18:1cis-9   5.008376049131687e−6 0.1204 482 482 C4:0   7.144243777499045e−7 0.01881 483 483 C14:0   3.97527101522368E−11 0.07208 484 484 C14:0   5.54360447823387E−12 0.07474 C18:1cis-9 9.3367189098250398E−8 0.1623 485 485 C14:0   5.54360447823387E−12 0.07474 C18:1cis-9 9.3367189098250398E−8 0.1623 486 486 C14:0  5.3271734853319101E−12 0.07482 C18:1cis-9 9.1488120708533204E−8 0.1625 487 487 C12:0  4.0196419308599601E−11 0.05107 C14:0  4.1348380093633499E−12 0.07585 C18:1cis-9 9.3842974698324402E−8 0.1637 488 488 C12:0   4.90176628620921E−12 0.05378 C14:0  1.4189374400058499E−12 0.07804 C18:1cis-9 6.4113364373631603E−8 0.1669 489 489 C12:0  4.7341555642885902E−12 0.05381 C14:0   1.34362366530036E−12 0.0781 C18:1cis-9 6.1248248552359403E−8 0.1672 490 490 C10:0  9.8960147737552498E−13 0.04697 C12:0  4.7101571732416404E−12 0.05382 C14:0  1.3301890805958101E−12 0.07811 C18:1cis-9 6.0322589767257897E−8 0.1672 491 491 C10:0  9.798085801963551E−13 0.04697 C12:0  4.6635122971289602E−12 0.05382 C14:0  1.2976574638717299E−12 0.07814 C18:1cis-9 5.9112639767034598E−8 0.1673 492 492 C10:0  9.4142521644103096E−13 0.04694 C12:0  4.4588898500815303E−12 0.0538 C14:0  1.1074265931101701E−12 0.07827 C18:1cis-9 5.2598129988874097E−8 0.1677 493 493 C10:0  9.4142521644103096E−13 0.04694 C12:0  4.4588898500815303E−12 0.0538 C14:0  1.1074265931101701E−12 0.07827 C18:1cis-9 5.2598129988874097E−8 0.1677 494 494 C10:0  9.4142521644103096E−13 0.04694 C12:0  4.4588898500815303E−12 0.0538 C14:0  1.1074265931101701E−12 0.07827 C18:1cis-9 5.2598129988874097E−8 0.1677 495 495 C6:0  8.6526872145536899E−13 0.03035 C8:0  3.2087627978321099E−16 0.02791 C12:0  8.8845096834888303E−11 0.07756 496 496 C8:0   1.26331219870779E−15 0.02731 497 497 C12:0  4.6053030477721603E−11 0.03385 C14:0  7.0501025182482499E−14 0.0546 C18:1cis-9  7.7836265611296704E−11 0.1328 498 498 C8:0  8.1070756299992592E−15 0.02516 499 499 C6:0  5.9695018587987398E−13 0.02775 C8:0  9.3485919420065296E−15 0.02407 500 500 C8:0  6.8938814238877397E−15 0.02504 501 501 C6:0   6.46832445103233E−14 0.03208 C8:0  6.4600902324189202E−18 0.02968 C10:0  5.8193809226297705E−14 0.07652 C12:0  4.5863400743583397E−12 0.08319 C14:0  9.0540251767141702E−12 0.1159 502 502 C8:0   1.96548709943932E−16 0.02974 C10:0  4.3338353448316299E−13 0.0774 C12:0  1.9534286026786999E−11 0.08476 C14:0  7.0492835056981495E−11 0.1157 503 503 C6:0  6.4678027041489594E−14 0.03211 C8:0  6.4352786975035901E−18 0.02973 C10:0  5.7618779673050795E−14 0.07672 C12:0  4.3857342114073604E−12 0.08347 C14:0  9.7064600229982607E−12 0.116 504 504 C6:0  5.8370300122890094E−14 0.03208 C8:0  5.9828049254068398E−18 0.02969 C10:0  5.6777583013235299E−14 0.07656 C12:0  4.4517957144493097E−12 0.08324 C14:0  9.1445131272512596E−12 0.1158 505 505 C6:0  5.8606259988554695E−14 0.03208 C8:0  6.0119529741251203E−18 0.02969 C10:0  5.7056605006040905E−14 0.07656 C12:0   4.47387414896631E−12 0.08324 C14:0  9.1900963229264497E−12 0.1158 506 506 C6:0  5.8370300122890094E−14 0.03208 C8:0  5.9828049254068398E−18 0.02969 C10:0  5.6777583013235299E−14 0.07656 C12:0  4.4517957144493097E−12 0.08324 C14:0  9.1445131272512596E−12 0.1158 507 507 C6:0  5.8370300122890094E−14 0.03208 C8:0  5.9828049254068398E−18 0.02969 C10:0  5.6777583013235299E−14 0.07656 C12:0  4.4517957144493097E−12 0.08324 C14:0  9.1445131272512596E−12 0.1158 508 508 C6:0  5.2844296657701699E−14 0.03229 C8:0  5.1216104581478098E−18 0.02988 C10:0  4.8502395204224899E−14 0.07712 C12:0   3.81704798800288E−12 0.08389 C14:0  7.2037733862774998E−12 0.117 509 509 C6:0  5.2844296657701699E−14 0.03229 C8:0  5.1216104581478098E−18 0.02988 C10:0  4.8502395204224899E−14 0.07712 C12:0   3.81704798800288E−12 0.08389 C14:0  7.2037733862774998E−12 0.117 510 510 C6:0  2.8691885622826501E−14 0.03241 C8:0  4.0955533857384502E−18 0.02978 C10:0  6.4836699238860897E−14 0.07623 C12:0  5.7624022031460201E−12 0.08265 C14:0   1.08271402419137E−11 0.1152 511 511 C6:0  8.6090132586570202E−14 0.03183 C8:0  5.9828049254068398E−18 0.02965 C10:0  4.0413783097584002E−14 0.0769 C12:0  3.0526698792752799E−12 0.08376 C14:0  6.3614861864064697E−12 0.1166 512 512 C6:0  7.4954777718639699E−13 0.02986 C8:0   1.1336634082662E−16 0.0278 C10:0  3.2527348815077898E−13 0.07227 C12:0   2.22798629292619E−11 0.07836 C14:0  1.6683600965042399E−11 0.1113 513 513 C6:0  7.4954777718639699E−13 0.02986 C8:0   1.1336634082662E−16 0.0278 C10:0  3.2527348815077898E−13 0.07227 C12:0   2.22798629292619E−11 0.07836 C14:0  1.6683600965042399E−11 0.1113 514 514 C6:0  6.8958658606376797E−14 0.03187 C8:0  4.8782858716258203E−18 0.02965 C10:0  3.5393630579030497E−14 0.07687 C12:0  2.6705116123192701E−12 0.08377 C14:0  6.5879292893616699E−12 0.1162 515 515 C8:0  2.9490947376025798E−15 0.02496 C12:0  6.1729347068226006E−11 0.07231 516 516 C8:0  3.6778283679910603E−15 0.0406 517 517 C6:0  7.8777696618941104E−14 0.03187 C8:0  5.4023514315186601E−18 0.02968 C10:0   3.60900965378338E−14 0.07703 C12:0   2.67015727068385E−12 0.08397 C14:0  6.7194813785435399E−12 0.1164 518 518 C6:0  7.8777696618941104E−14 0.03187 C8:0  5.4023514315186601E−18 0.02968 C10:0   3.60900965378338E−14 0.07703 C12:0   2.67015727068385E−12 0.08397 C14:0  6.7194813785435399E−12 0.1164 519 519 C6:0  7.8777696618941104E−14 0.03187 C8:0  5.4023514315186601E−18 0.02968 C10:0   3.60900965378338E−14 0.07703 C12:0   2.67015727068385E−12 0.08397 C14:0  6.7194813785435399E−12 0.1164 520 520 C6:0  7.8777696618941104E−14 0.03187 C8:0  5.4023514315186601E−18 0.02968 C10:0   3.60900965378338E−14 0.07703 C12:0   2.67015727068385E−12 0.08397 C14:0  6.7194813785435399E−12 0.1164 521 521 C6:0  7.8777696618941104E−14 0.03187 C8:0  5.4023514315186601E−18 0.02968 C10:0   3.60900965378338E−14 0.07703 C12:0   2.67015727068385E−12 0.08397 C14:0  6.7194813785435399E−12 0.1164 522 522 C6:0  7.8777696618941104E−14 0.03187 C8:0  5.4023514315186601E−18 0.02968 C10:0   3.60900965378338E−14 0.07703 C12:0   2.67015727068385E−12 0.08397 C14:0  6.7194813785435399E−12 0.1164 523 523 C6:0  7.8777696618941104E−14 0.03187 C8:0  5.4023514315186601E−18 0.02968 C10:0   3.60900965378338E−14 0.07703 C12:0   2.67015727068385E−12 0.08397 C14:0  6.7194813785435399E−12 0.1164 524 524 C6:0  7.8777696618941104E−14 0.03187 C8:0  5.4023514315186601E−18 0.02968 C10:0   3.60900965378338E−14 0.07703 C12:0   2.67015727068385E−12 0.08397 C14:0  6.7194813785435399E−12 0.1164 525 525 C6:0  6.3731745223760804E−14 0.03183 C8:0  5.5352228294095803E−18 0.02952 C10:0  4.5014602845649898E−14 0.07634 C12:0   3.40361060193182E−12 0.08313 C14:0  8.6981209348386702E−12 0.1152 526 526 C6:0  7.8777696618941104E−14 0.03187 C8:0  5.4023514315186601E−18 0.02968 C10:0   3.60900965378338E−14 0.07703 C12:0   2.67015727068385E−12 0.08397 C14:0  6.7194813785435399E−12 0.1164 527 527 C6:0  7.8777696618941104E−14 0.03187 C8:0  5.4023514315186601E−18 0.02968 C10:0   3.60900965378338E−14 0.07703 C12:0   2.67015727068385E−12 0.08397 C14:0  6.7194813785435399E−12 0.1164 528 528 C6:0  8.6099510700857397E−13 0.02985 C8:0  1.2560358657241399E−16 0.02782 C10:0  3.3337528695859998E−13 0.07241 C12:0  2.2389699973462499E−11 0.07853 C14:0  1.7103561141567702E−11 0.1115 529 529 C6:0  7.8777696618941104E−14 0.03187 C8:0  5.4023514315186601E−18 0.02968 C10:0   3.60900965378338E−14 0.07703 C12:0   2.67015727068385E−12 0.08397 C14:0  6.7194813785435399E−12 0.1164 530 530 C6:0  8.9997524897581702E−14 0.03185 C8:0  6.0412432342423701E−18 0.02969 C10:0   3.75352307596589E−14 0.0771 C12:0  2.7099870413625398E−12 0.08408 C14:0  6.9569812272975103E−12 0.1165 531 531 C6:0  8.9997524897581702E−14 0.03185 C8:0  6.0412432342423701E−18 0.02969 C10:0   3.75352307596589E−14 0.0771 C12:0  2.7099870413625398E−12 0.08408 C14:0  6.9569812272975103E−12 0.1165 532 532 C6:0   1.17069127353711E−13 0.03179 C8:0  7.3378389392513199E−18 0.02966 C10:0  4.1211431392182997E−14 0.0771 C12:0   2.87594935447973E−12 0.08411 C14:0  7.4577782254279306E−12 0.1165 533 533 C6:0   1.17069127353711E−13 0.03179 C8:0  7.3378389392513199E−18 0.02966 C10:0  4.1211431392182997E−14 0.0771 C12:0   2.87594935447973E−12 0.08411 C14:0  7.4577782254279306E−12 0.1165 534 534 C6:0   1.17069127353711E−13 0.03179 C8:0  7.3378389392513199E−18 0.02966 C10:0  4.1211431392182997E−14 0.0771 C12:0   2.87594935447973E−12 0.08411 C14:0  7.4577782254279306E−12 0.1165 535 535 C6:0   1.17069127353711E−13 0.03179 C8:0  7.3378389392513199E−18 0.02966 C10:0  4.1211431392182997E−14 0.0771 C12:0   2.87594935447973E−12 0.08411 C14:0  7.4577782254279306E−12 0.1165 536 536 C6:0   1.18050197534709E−13 0.03176 C8:0  7.4819301094848397E−18 0.02967 C10:0   4.02121462221512E−14 0.07717 C12:0  2.7779431024913298E−12 0.08421 C14:0  7.2751038856886499E−12 0.1166 537 537 C6:0  9.7869401731918304E−14 0.03203 C8:0  6.4986965004188899E−18 0.02987 C10:0  3.9408520446929702E−14 0.07758 C12:0  2.9474123618934201E−12 0.08452 C14:0  7.4932481165886701E−12 0.1171 538 538 C6:0  2.3103353192058902E−13 0.0314 C8:0   1.51467923500645E−17 0.02941 C10:0  5.8748065597100296E−14 0.0767 C12:0  3.6310663124227601E−12 0.08379 C14:0  9.1888404317268005E−12 0.1161 539 539 C6:0  4.5583011817933699E−14 0.0321 C8:0  3.7526867917927399E−18 0.02976 C10:0   2.31583193419613E−14 0.07742 C12:0  1.6498972566502901E−12 0.08455 C14:0  4.4696569228457802E−12 0.1171 540 540 C12:0  3.9320152099305201E−11 0.05508 541 541 C6:0  7.3485275600098796E−13 0.03026 C8:0  2.1501128207339601E−16 0.02804 C10:0   4.64277210485625E−13 0.07274 C12:0   2.95950043511028E−11 0.07888 C14:0  2.0058022469162001E−11 0.1123 542 542 C6:0  6.1189066506996495E−13 0.03033 C8:0   1.37811661932649E−16 0.02805 C10:0  4.4850896787682901E−13 0.07271 C12:0  3.0041756692055502E−11 0.07878 543 543 C8:0  6.2974756280658802E−15 0.01766 C10:0  3.6772846519945002E−13 0.04857 C12:0  5.2376115799734699E−12 0.05437 C14:0   2.84669598414608E−12 0.07758 C18:1cis-9 2.1778978217475099E−8 0.1767 544 544 C6:0  2.9781681949215698E−15 0.0328 C8:0  1.8205919140614801E−18 0.02936 C10:0   5.29450458855621E−14 0.07462 C12:0  4.2126395123090899E−12 0.08113 C14:0   5.31729041193598E−12 0.114 545 545 C6:0  1.9935163607514599E−14 0.03147 C8:0  6.4075463746674299E−18 0.02855 C10:0  8.9794236047964494E−14 0.07292 C12:0  5.6939448076521802E−12 0.07965 C14:0   1.19747216505542E−11 0.1101 546 546 C6:0  6.1577210140203499E−15 0.03156 C8:0  6.5935949195694402E−18 0.0281 C10:0  1.4120329594138201E−13 0.07137 C12:0  9.4198441244611398E−12 0.07764 C14:0  9.1388972384758007E−12 0.1097 547 547 C6:0  3.3175615415457701E−15 0.03213 C8:0  2.4008482035435101E−18 0.02871 C10:0  6.3831124638089105E−14 0.07298 C12:0   4.76859011214647E−12 0.0794 C14:0  5.4774797253576498E−12 0.1118 548 548 C8:0  8.9441680841612995E−15 0.0224 C14:0  7.7898404836716797E−11 0.09264 549 549 C8:0  8.9441680841612995E−15 0.0224 C14:0  7.7898404836716797E−11 0.09264 550 550 C8:0  8.9441680841612995E−15 0.0224 C14:0  7.7898404836716797E−11 0.09264 551 551 C8:0  4.6302927506374902E−16 0.02468 C10:0  5.8358489429137297E−13 0.06482 C12:0  1.8359609669685801E−11 0.07134 C14:0   1.74594372230884E−11 0.1009 552 552 C14:0  8.9143996334826603E−11 0.09232 553 553 C14:0  8.9143996334826603E−11 0.09232 554 554 C6:0   1.98362859176475E−14 0.0311 C8:0  8.2060250520263206E−18 0.02815 C10:0   8.40747139441296E−14 0.07233 C12:0  6.6494155920830596E−12 0.07852 C14:0  3.6989178961073298E−12 0.1122 555 555 C6:0  1.9836814556188401E−14 0.0311 C8:0  8.0871943049434207E−18 0.02815 C10:0  8.1621684319154994E−14 0.07235 C12:0  6.4539668067409299E−12 0.07855 C14:0   3.53729967674195E−12 0.1122 556 556 C6:0  1.9836814556188401E−14 0.0311 C8:0  8.0871943049434207E−18 0.02815 C10:0  8.1621684319154994E−14 0.07235 C12:0  6.4539668067409299E−12 0.07855 C14:0   3.53729967674195E−12 0.1122 557 557 C6:0  1.9836814556188401E−14 0.0311 C8:0  8.0871943049434207E−18 0.02815 C10:0  8.1621684319154994E−14 0.07235 C12:0  6.4539668067409299E−12 0.07855 C14:0   3.53729967674195E−12 0.1122 558 558 C6:0  1.9836814556188401E−14 0.0311 C8:0  8.0871943049434207E−18 0.02815 C10:0  8.1621684319154994E−14 0.07235 C12:0  6.4539668067409299E−12 0.07855 C14:0   3.53729967674195E−12 0.1122 559 559 C6:0   1.94523350166284E−14 0.0311 C8:0  7.7033972493254596E−18 0.02816 C10:0  7.7692815395340406E−14 0.0724 C12:0  6.1716936497831503E−12 0.07861 C14:0   3.39958755179364E−12 0.1123 560 560 C6:0  4.6035529933010502E−14 0.02061 C8:0  1.0759089800870299E−18 0.01951 C10:0  7.5972957518285096E−16 0.0523 C12:0  4.7934482954406602E−14 0.05769 C14:0  5.1964277076951602E−14 0.08118 561 561 C6:0   1.94523350166284E−14 0.0311 C8:0  7.7033972493254596E−18 0.02816 C10:0  7.7692815395340406E−14 0.0724 C12:0  6.1716936497831503E−12 0.07861 C14:0   3.39958755179364E−12 0.1123 562 562 C6:0   1.94523350166284E−14 0.0311 C8:0  7.7033972493254596E−18 0.02816 C10:0  7.7692815395340406E−14 0.0724 C12:0  6.1716936497831503E−12 0.07861 C14:0   3.39958755179364E−12 0.1123 563 563 C6:0   1.94523350166284E−14 0.0311 C8:0  7.7033972493254596E−18 0.02816 C10:0  7.7692815395340406E−14 0.0724 C12:0  6.1716936497831503E−12 0.07861 C14:0   3.39958755179364E−12 0.1123 564 564 C6:0   1.94523350166284E−14 0.0311 C8:0  7.7033972493254596E−18 0.02816 C10:0  7.7692815395340406E−14 0.0724 C12:0  6.1716936497831503E−12 0.07861 C14:0   3.39958755179364E−12 0.1123 565 565 C6:0   1.94523350166284E−14 0.0311 C8:0  7.7033972493254596E−18 0.02816 C10:0  7.7692815395340406E−14 0.0724 C12:0  6.1716936497831503E−12 0.07861 C14:0   3.39958755179364E−12 0.1123 566 566 C6:0  2.0330308130571501E−14 0.03109 C8:0  7.5183934897634105E−18 0.02818 C10:0  7.1799581917588301E−14 0.07253 C12:0  5.7283518442957199E−12 0.07876 C14:0  3.1089957748248099E−12 0.1125 567 567 C6:0  4.1715114945833403E−14 0.03076 C8:0  1.8402369977282401E−17 0.02788 C10:0   1.49738523552676E−13 0.07168 C12:0   1.12072025696161E−11 0.07777 C14:0   6.4836206798199E−12 0.111 568 568 C6:0  2.0330308130571501E−14 0.03109 C8:0  7.5183934897634105E−18 0.02818 C10:0  7.1799581917588301E−14 0.07253 C12:0  5.7283518442957199E−12 0.07876 C14:0  3.1089957748248099E−12 0.1125 569 569 C6:0  2.0330308130571501E−14 0.03109 C8:0  7.5183934897634105E−18 0.02818 C10:0  7.1799581917588301E−14 0.07253 C12:0  5.7283518442957199E−12 0.07876 C14:0  3.1089957748248099E−12 0.1125 570 570 C6:0  2.0330308130571501E−14 0.03109 C8:0  7.5183934897634105E−18 0.02818 C10:0  7.1799581917588301E−14 0.07253 C12:0  5.7283518442957199E−12 0.07876 C14:0  3.1089957748248099E−12 0.1125 571 571 C6:0  1.5515552482962701E−15 0.01787 C8:0  5.8390249193305097E−17 0.01513 C10:0  6.6990538012810396E−13 0.03851 C12:0  8.9153993573030205E−11 0.04103 C14:0   1.97577389061098E−11 0.05987 572 572 C6:0  2.3104976993783701E−14 0.03115 C8:0  6.7887314298445697E−18 0.02833 C10:0  5.7239491626225202E−14 0.07312 C12:0  4.6964631674301602E−12 0.07941 C14:0   2.37837536205307E−12 0.1136 573 573 C6:0  2.3104976993783701E−14 0.03115 C8:0  6.7887314298445697E−18 0.02833 C10:0  5.7239491626225202E−14 0.07312 C12:0  4.6964631674301602E−12 0.07941 C14:0   2.37837536205307E−12 0.1136 574 574 C6:0  2.3104976993783701E−14 0.03115 C8:0  6.7887314298445697E−18 0.02833 C10:0  5.7239491626225202E−14 0.07312 C12:0  4.6964631674301602E−12 0.07941 C14:0   2.37837536205307E−12 0.1136 575 575 C6:0  2.3104976993783701E−14 0.03115 C8:0  6.7887314298445697E−18 0.02833 C10:0  5.7239491626225202E−14 0.07312 C12:0  4.6964631674301602E−12 0.07941 C14:0   2.37837536205307E−12 0.1136 576 576 C6:0  2.3104976993783701E−14 0.03115 C8:0  6.7887314298445697E−18 0.02833 C10:0  5.7239491626225202E−14 0.07312 C12:0  4.6964631674301602E−12 0.07941 C14:0   2.37837536205307E−12 0.1136 577 577 C6:0   1.11813746694359E−13 0.03043 C8:0  4.3583673414414098E−17 0.02773 C10:0  2.3241356856986502E−13 0.07157 C12:0  1.5800231331830499E−11 0.0777 C14:0  6.7806708187726702E−12 0.1116 578 578 C6:0  5.1094854026620902E−15 0.0174 C8:0   1.86730902209013E−17 0.01524 C10:0   1.01891692801114E−13 0.0395 C12:0  1.4659211231729599E−11 0.04232 C14:0  3.6985796833596601E−12 0.06142 579 579 C6:0  3.1974097320826697E−14 0.03109 C8:0   7.09233371815551E−18 0.02841 C10:0   4.81821658986466E−14 0.07359 C12:0  3.9870678737670197E−12 0.07995 C14:0  1.9798379235384702E−12 0.1145 580 580 C6:0  5.2326051203402503E−14 0.03085 C8:0  1.1422488315846599E−17 0.02825 C10:0  7.2930274343917101E−14 0.07313 C12:0  5.9934868100761697E−12 0.07937 C14:0   2.65358421316355E−12 0.1139 581 581 C6:0  9.2737948003598496E−13 0.03034 C8:0   1.83293017350549E−15 0.02722 582 582 C6:0  8.5251120766593496E−13 0.0304 C8:0  1.8149939038893202E−15 0.02724 583 583 C6:0  8.6956358601963199E−13 0.03043 C8:0  1.6863492757359999E−15 0.02731 584 584 C6:0  1.5640280767144001E−13 0.03117 C8:0  2.4049504936820502E−16 0.0279 C14:0  7.9905304249101799E−11 0.1093 585 585 C6:0  3.6882234002487498E−14 0.03257 C8:0  1.8383449209801899E−18 0.03035 C10:0   1.36924786745353E−14 0.07896 C12:0  9.7634820058186092E−13 0.08637 C14:0   1.72486244075151E−12 0.1207 586 586 C8:0  1.5140034590119901E−15 0.02442 C10:0  3.3831081182036098E−13 0.06588 C12:0  7.5666702304575396E−12 0.07313 C14:0  6.2309245299310697E−12 0.1036 587 587 C14:0  9.3056726983825702E−11 0.06549 588 588 C12:0   3.45891155467598E−11 0.04769 C14:0   1.39249980298512E−12 0.07174 C18:1cis-9 2.6283604811214599E−8 0.1606 589 589 C10:0  3.1143358297115698E−13 0.0447 C12:0  5.4053323750460298E−12 0.04984 C14:0  1.1641333915061901E−13 0.07546 C18:1cis-9 3.9350672508404297E−9 0.1706 590 590 C6:0  6.6291988274311306E−14 0.03217 C8:0  3.7528511457224296E−18 0.03001 C10:0  1.5256093268115298E−14 0.07863 C12:0  8.4994339979418203E−13 0.08639 C14:0  8.7499116323703404E−13 0.122 591 591 C6:0  6.6291988274311306E−14 0.03217 C8:0  3.7528511457224296E−18 0.03001 C10:0  1.5256093268115298E−14 0.07863 C12:0  8.4994339979418203E−13 0.08639 C14:0  8.7499116323703404E−13 0.122 592 592 C6:0   3.39681306090115E−13 0.03129 C8:0  4.0116611887275599E−17 0.02912 C10:0   1.08848446213586E−13 0.07616 C12:0  4.6324517499887898E−12 0.0837 C14:0  5.0126633891006798E−12 0.118 593 593 C8:0   2.18105714910406E−16 0.02826 C10:0  4.5123976060765801E−13 0.07377 C12:0  1.6130877182238299E−11 0.08104 C14:0   1.7030748351964E−11 0.1143 594 594 C8:0  3.9585123328324296E−15 0.02648 C12:0  5.3891410098447302E−11 0.07723 C14:0   3.7992610279941E−11 0.1099 595 595 C4:0 1.1618660950668801E−7 0.02482 C6:0  1.87506150599083E−5 0.01168 596 596 C4:0  8.5775026528943598E−10 0.04225 C6:0 2.4443641788527101E−5 0.01692 597 597 C4:0 2.8770112674904698E−7 0.02885 C6:0   1.9727754006559E−7 0.01701 598 598 C4:0 5.2592132122375695E−7 0.03631 599 599 C4:0  8.3230409248311496E−10 0.04228 C6:0 2.3940221412394202E−5 0.01694 600 600 C4:0  2.86237147958134E−7 0.02886 C6:0   1.9727754006559E−7 0.01701 601 601 C4:0  1.24382885819805E−9 0.04174 C6:0 3.1712579023418199E−5 0.01665 602 602 C4:0  1.15355196196173E−9 0.04183 C6:0 3.1220701089658397E−5 0.01666 603 603 C6:0 1.4767300384339199E−5 0.05324 604 604 C4:0  1.74611849994922E−7 0.03013 C6:0 1.6590699704015801E−7 0.01755 605 605 C4:0  9.1602659442445695E−10 0.04152 C6:0 3.2890832433734701E−5 0.01639 606 606 C4:0 2.5073060684692002E−7 0.02976 C6:0 2.9064348122720599E−7 0.01721 607 607 C4:0 1.5452471254047201E−7 0.03026 C6:0  1.90370428670056E−7 0.01747 608 608 C4:0 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 9.92548073128146E−8 0.02642 C6:0  2.39436512069864E−7 0.0149 628 628 C6:0 8.0555988387369701E−6 0.01203 C8:0 1.1563117021960201E−6 0.01057 C10:0 6.0606651550769701E−6 0.02945 629 629 C4:0 9.5785004332955504E−8 0.02645 C6:0  2.05485444983831E−7 0.01498 630 630 C6:0 3.0897053714715597E−5 0.04728 631 631 C6:0 3.0897053714715597E−5 0.04728 632 632 C6:0 3.0897053714715597E−5 0.04728 633 633 C4:0  1.08126790372323E−9 0.0411 C6:0  2.10216527171677E−5 0.01669 634 634 C4:0  1.08126790372323E−9 0.0411 C6:0  2.10216527171677E−5 0.01669 635 635 C4:0  1.08126790372323E−9 0.0411 C6:0  2.10216527171677E−5 0.01669 636 636 C4:0  1.08671142852652E−9 0.04109 C6:0  2.11312165605433E−5 0.01668 637 637 C4:0 2.9576637385185398E−9 0.03848 C6:0  1.63824025137785E−5 0.01625 638 638 C4:0 1.0231515461465901E−9 0.04116 C6:0 2.0696377017675298E−5 0.0167 639 639 C4:0 1.0544456822863601E−9 0.04113 C6:0 2.0165458950355998E−5 0.01672 640 640 C4:0 1.0544456822863601E−9 0.04113 C6:0 2.0165458950355998E−5 0.01672 641 641 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0.00903 777 777 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640771250574599E−5 0.00903 778 778 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640771250574599E−5 0.00903 779 779 C4:0 1.9144780350299398E−5 0.01628 C6:0 3.8061485537182102E−5 0.00914 780 780 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640771250574599E−5 0.00903 781 781 C4:0 2.1021941739060599E−5 0.01622 C6:0  4.92123990752145E−5 0.00904 782 782 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640771250574599E−5 0.00903 783 783 C4:0 3.8061763425272699E−5 0.0156 C6:0 2.0376218965095099E−5 0.00939 784 784 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640771250574599E−5 0.00903 785 785 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640771250574599E−5 0.00903 786 786 C4:0 4.1375982509336099E−5 0.01565 C6:0 6.8346132976930193E−5 0.00885 787 787 C4:0 2.1021941739060599E−5 0.01622 C6:0  4.92123990752145E−5 0.00904 788 788 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640771250574599E−5 0.00903 789 789 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640771250574599E−5 0.00903 790 790 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640771250574599E−5 0.00903 791 791 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640771250574599E−5 0.00903 792 792 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640771250574599E−5 0.00903 793 793 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640771250574599E−5 0.00903 794 794 C4:0  1.31074434096477E−5 0.01679 C6:0 6.7280814906985498E−5 0.00895 795 795 C4:0 2.0912947997407001E−5 0.01622 C6:0 4.7392096983275499E−5 0.00903 796 796 C4:0  2.46995942865043E−5 0.01612 C6:0 5.1251123056161799E−5 0.00905 797 797 C4:0 3.1221017868571102E−5 0.0159 C6:0 8.9856519429302496E−5 0.00899 798 798 C4:0 1.4541485158180799E−5 0.0167 C6:0 5.4291331059260198E−5 0.00904 799 799 C4:0 1.4541485158180799E−5 0.0167 C6:0 5.4291331059260198E−5 0.00904 800 800 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640771250574599E−5 0.00903 801 801 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640771250574599E−5 0.00903 802 802 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640771250574599E−5 0.00903 803 803 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640771250574599E−5 0.00903 804 804 C4:0 3.2720344437166301E−5 0.01584 C6:0 3.7666353554999901E−5 0.00915 805 805 C4:0  2.04826263644331E−5 0.01625 C6:0 4.6366482807218097E−5 0.00905 806 806 C4:0 3.4471807344232797E−5 0.01578 C6:0 5.4863189909845899E−5 0.00895 807 807 C4:0 3.4471292991151098E−5 0.01574 C6:0 4.5929800536192898E−5 0.00902 808 808 C4:0 3.5752706598229098E−5 0.0157 C6:0 4.7640329357455599E−5 0.009 809 809 C4:0 3.6127819240129302E−5 0.01581 C6:0 5.1524819156835798E−5 0.00903 810 810 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640771250574599E−5 0.00903 811 811 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640771250574599E−5 0.00903 812 812 C4:0 3.2891245107355698E−5 0.01583 C6:0 6.5542446369305698E−5 0.00886 813 813 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640329357455599E−5 0.00903 814 814 C4:0 4.8393241944496497E−5 0.01552 815 815 C4:0 2.1021941739060599E−5 0.01623 C6:0 4.3821245403415497E−5 0.00908 816 816 C4:0 4.2028903023284097E−5 0.01585 817 817 C4:0 3.0379040074163501E−6 0.0185 818 818 C4:0 3.5091424976887601E−6 0.01842 C6:0 8.1248071273996598E−5 0.00912 819 819 C4:0 3.5091424976887601E−6 0.01842 C6:0 8.1248071273996598E−5 0.00912 820 820 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640329357455599E−5 0.00903 821 821 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640329357455599E−5 0.00903 822 822 C4:0 1.6814180189790299E−5 0.01655 C6:0  1.49213326470014E−5 0.00970 823 823 C4:0 2.1241646155138502E−5 0.01621 C6:0 4.7640329357455599E−5 0.00903 824 824 C4:0  2.62922196623481E−5 0.01622 C6:0 8.9292516060599403E−5 0.00881 825 825 C4:0 8.9039211208208401E−7 0.01957 826 826 C4:0 1.6382639126981499E−5 0.01642 C6:0 4.9674118045879501E−5 0.00901 827 827 C4:0 2.0912947997407001E−5 0.01622 C6:0 4.7392096983275499E−5 0.00903 828 828 C4:0 2.1241646155138502E−5 0.01621 C6:0 6.1148459045767806E−5 0.00903 829 829 C4:0 2.1241646155138502E−5 0.01621 C6:0 6.1148459045767806E−5 0.00903 830 830 C4:0 2.1241646155138502E−5 0.01621 C6:0 6.1148459045767806E−5 0.00903 831 831 C4:0 2.1241646155138502E−5 0.01621 C6:0 6.1148459045767806E−5 0.00903 832 832 C4:0 8.7898627092370901E−5 0.0149 833 833 C4:0 8.7898627092370901E−5 0.0149 834 834 C4:0 5.5149093214902699E−5 0.01537 835 835 C4:0 7.0159993557734204E−5 0.0151 836 836 C4:0 8.7898627092370901E−5 0.0149 837 837 C4:0 5.8110516031289698E−5 0.01513 838 838 C4:0 8.7898627092370901E−5 0.0149 839 839 C4:0 8.7898627092370901E−5 0.0149 840 840 C4:0 8.8360982493528294E−5 0.01489 841 841 C4:0 8.2105101627525799E−5 0.01495 842 842 C4:0 8.7898627092370901E−5 0.0149 843 843 C4:0 8.7898627092370901E−5 0.0149 844 844 C4:0 8.8360982493528294E−5 0.01489 845 845 C4:0 8.8360982493528294E−5 0.01489 846 846 C4:0 8.7898627092370901E−5 0.0149 847 847 C4:0 9.2149492721276202E−5 0.01467 848 848 C4:0 4.6171079390002102E−5 0.01546 849 849 C4:0 5.7807590208202899E−5 0.01536 850 850 C4:0 5.7807590208202899E−5 0.01536 851 851 C4:0 5.6610693840423797E−5 0.01537 852 852 C4:0 5.6610693840423797E−5 0.01537 853 853 C4:0 5.6610693840423797E−5 0.01537 854 854 C4:0 5.6610693840423797E−5 0.01537 855 855 C4:0 5.6610693840423797E−5 0.01537 856 856 C4:0 5.6610693840423797E−5 0.01537 857 857 C4:0 5.6610693840423797E−5 0.01537 858 858 C4:0 5.6610693840423797E−5 0.01537 859 859 C4:0 6.7283419035809103E−5 0.01532 860 860 C4:0 6.6932030681008002E−5 0.01533 861 861 C4:0 6.7283419035809103E−5 0.01532 862 862 C4:0 7.1647532994452502E−5 0.01523 863 863 C4:0 6.7283419035809103E−5 0.01532 864 864 C4:0 6.6932030681008002E−5 0.01533 865 865 C4:0 6.7283419035809103E−5 0.01532 866 866 C4:0  4.18112831510607E−5 0.0159 867 867 C4:0 6.7283419035809103E−5 0.01532 868 868 C4:0 6.7283419035809103E−5 0.01532 869 869 C4:0 6.7283419035809103E−5 0.01532 870 870 C4:0 2.1916270366483601E−5 0.0161 871 871 C4:0 6.7232554716256698E−6 0.01723 872 872 C4:0 9.8623264055202404E−6 0.01731 C6:0 7.0898406466732503E−5 0.00903 873 873 C4:0 6.7283419035809103E−5 0.01532 874 874 C4:0 7.5107465797901495E−5 0.01521 875 875 C4:0 6.8349208848892803E−5 0.01534 876 876 C4:0 6.8349208848892803E−5 0.01534 877 877 C4:0 6.8349208848892803E−5 0.01534 878 878 C4:0 6.8349208848892803E−5 0.01534 879 879 C4:0 6.8349062214906504E−5 0.01535 880 880 C4:0 9.9701087779821606E−5 0.01495 881 881 C4:0 6.8349208848892803E−5 0.01534 882 882 C4:0 6.8349208848892803E−5 0.01534 883 883 C4:0 6.8349208848892803E−5 0.01534 884 884 C4:0 6.8349208848892803E−5 0.01534 885 885 C4:0 6.8349208848892803E−5 0.01534 886 886 C4:0 6.8349208848892803E−5 0.01534 887 887 C12:0 9.9609642871672794E−6 0.02894 888 888 C12:0 7.3791347134148397E−6 0.02914 889 889 C10:0   2.9212843771927E−7 0.08302 C12:0   4.0916532283562E−7 0.09665 C14:0 6.2547862297914996E−9 0.1561 890 890 C10:0 3.9921713195219098E−6 0.02533 C12:0 1.3014523386799699E−6 0.03131 C14:0 1.2427901953404301E−7 0.04814 891 891 C10:0  1.54149843323962E−6 0.02629 C12:0 5.0470287011740601E−7 0.03238 C14:0 3.7693339495266303E−8 0.04989 892 892 C14:0 8.2945697001932298E−7 0.04471 893 893 C12:0 7.6509952186251208E−6 0.02902 894 894 C12:0 9.5075588436017696E−6 0.0289 895 895 C12:0 7.5723131110883999E−6 0.029 896 896 C12:0 7.5723131110883999E−6 0.029 897 897 C12:0  7.07995488380744E−6 0.02931 898 898 C12:0 7.7707308024999804E−6 0.02898 899 899 C10:0 2.8623391726682899E−7 0.08273 C12:0 3.9884613447224798E−7 0.09633 C14:0 5.9761084872016902E−9 0.1557 900 900 C10:0  3.36786191733193E−6 0.08683 C12:0 4.8061182424494699E−6 0.1007 C14:0 1.1442574673726901E−7 0.1646 901 901 C12:0 8.2678409466809695E−6 0.02913 902 902 C10:0  1.33292595395347E−7 0.08454 C12:0  1.95277480454429E−7 0.09831 C14:0 3.7400036131947403E−9 0.1569 903 903 C10:0 1.8523529872076101E−8 0.08735 C12:0 3.7827293716781299E−8 0.1007 C14:0 1.1582149669298101E−9 0.157 C18:1cis-11  4.4636936092160943e−7 0.3692 904 904 C10:0 3.2024672488398301E−7 0.08293 C12:0 4.8431470042416999E−7 0.09625 C14:0 5.9755054826785199E−9 0.1567 905 905 C10:0 2.8916935986997599E−7 0.0827 C12:0 4.0294123092189202E−7 0.09629 C14:0 5.9161307729461301E−9 0.1557 906 906 C10:0 2.8916935986997599E−7 0.0827 C12:0 4.0294123092189202E−7 0.09629 C14:0 5.9161307729461301E−9 0.1557 907 907 C10:0 2.8916935986997599E−7 0.0827 C12:0 4.0294123092189202E−7 0.09629 C14:0 5.9161307729461301E−9 0.1557 908 908 C10:0 2.9064838996105402E−7 0.08269 C12:0 4.0294123092189202E−7 0.09629 C14:0 5.8863686023439203E−9 0.1558 909 909 C10:0 2.9064838996105402E−7 0.08269 C12:0 4.0294123092189202E−7 0.09629 C14:0 5.8863686023439203E−9 0.1558 910 910 C10:0 2.9064838996105402E−7 0.08269 C12:0 4.0294123092189202E−7 0.09629 C14:0 5.8863686023439203E−9 0.1558 911 911 C10:0 5.2145845868009402E−9 0.07313 C12:0 7.4985219009258199E−9 0.08529 C14:0  4.0745822009914199E−11 0.1371 C18:1cis-10   6.989162215542427e−8 0.3182 912 912 C10:0   1.7523345672918E−6 0.06245 C12:0 1.6560556975478499E−6 0.07378 C14:0 9.9754172683479696E−8 0.1156 913 913 C10:0  1.05438969857545E−6 0.0629 C12:0 1.0985192789977301E−6 0.07402 C14:0 4.6106555954215799E−8 0.117 914 914 C10:0 2.8916935986997599E−7 0.08272 C12:0 4.0294123092189202E−7 0.09632 C14:0 5.8863686023439203E−9 0.1558 915 915 C10:0 2.8916935986997599E−7 0.08272 C12:0 4.0294123092189202E−7 0.09632 C14:0 5.8863686023439203E−9 0.1558 916 916 C10:0 3.7224648692225599E−6 0.02668 C12:0 1.4376674114458401E−6 0.0328 C14:0  1.4761793085685999E−10 0.06159 C18:1cis-9   3.3856835714823224e−11 0.1794

On BTA11, a series of highly significant markers spanning the progestogen associated endometrial protein (PAEP) gene were found. PAEP encodes the β-lactoglobulin, which is one of the major proteins in milk. The markers were found to affect C16:0 and C18:1 cis-9 in an opposite manner. On BTA13, markers with effect on de novo-synthesis of short and medium-chained acids were detected in a region that spans the nuclear receptor coactivator 6 (NCOA6) gene, which is involved in regulation of bovine milk fat synthesis. For BTA17, significant associations for C4:0 and C6:0 were detected for markers near and within acetoacetyl-CoA synthetase (AACS) which activate ketone bodies for fatty acid synthesis. BTA19 were found to contain two distinct regions with effect on fatty acid composition. The first region is close to (although not overlapping) the sterol regulatory element binding transcription factor 1 (SREBF1) gene, which is one of the major regulators of fatty acid synthesis. The second region overlaps the fatty acid synthase (FASN) gene. Within each region, extensive linkage disequilibrium among markers makes it difficult to identify the underlying causal polymorphism. Some of the markers are situated in coding sequences and cause a shift in amino acid (P #446, P #463, P #523, P #564, P #597, P #748, P #749, P #781, P #782), while some others are positioned in putative regulatory sequences immediately upstream or downstream of the gene. Such markers are traditionally regarded as more likely to be causal as compared to markers in introns or intergenic regions, since they may affect protein sequence or gene expression. However, recent research indicates that also markers in introns and intergenic regions as well as exonic markers not causing amino acids shifts may have important biological roles, and all of the markers should be regarded as putatively causal. 

1.-34. (canceled)
 35. A method for selecting a cattle which possesses a genotype which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, the method comprising: determining the presence of at least one allele, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle; and selecting said cattle when the at least one allele, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, is present; wherein the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #242-P #246, P #311, P #312, P #314-P #334, P #339, P #340, P #343, P #344 and P #346-481 listed in table
 1. 36. The method according to claim 35, wherein the polymorphisms are either spanning the progestogen associated endometrial protein (PAEP) gene on BTA11; or in strong linkage disequilibrium with the polymorphisms spanning the PAEP gene on BTA11, wherein two polymorphisms are in strong linkage disequilibrium if r2≥0.7.
 37. The method according to claim 35, wherein the polymorphisms are spanning the PAEP gene on BTA11.
 38. The method according to claim 35, wherein the at least one allele is a “non-fat allele” for C:16:0 and a “fat allele” for C18:1 cis9.
 39. The method according to claim 35, wherein the desired milk fatty acid composition is decreased amount of C16:0 and increased amount of C18:1 cis-9 in milk.
 40. The method according to claim 35, wherein the polymorphisms are either spanning the progestogen associated endometrial protein (PAEP) gene on BTA11; or in strong linkage disequilibrium with the polymorphisms spanning the PAEP gene on BTA11, wherein two polymorphisms are in strong linkage disequilibrium if r2≥0.7; the at least one allele is a “non-fat allele” for C:16:0 and a “fat allele” for C18:1 cis9; and the desired milk fatty acid composition is decreased amount of C16:0 and increased amount of C18:1 cis-9 in milk.
 41. The method according to claim 35, wherein the cattle is homozygote with respect to the at least one allele.
 42. The method according to claim 35, wherein the method comprises determining the identity of one or more nucleotides of at least one allele of at least one polymorphism, which in a female milk-producing cattle is indicative of a desired milk fatty acid composition, within the genome of said cattle, said at least one polymorphism being located within said genome at a position corresponding to position 60 of the nucleotide sequence set forth in any one of SEQ ID NOs: 242-246, 311, 312, 314-334, 339, 340, 343, 344 and 346-481; or at a position corresponding to position 60 of a nucleotide sequence which is derived from any one of SEQ ID NOs: 242-246, 311, 312, 314-334, 339, 340, 343, 344 and 346-481 by 1 to 30 nucleotide substitutions; and selecting said cattle when the one or more nucleotides of the at least one allele is one or more nucleotides corresponding to the allele which in a female milk-producing cattle is indicative of the desired milk fatty acid composition.
 43. The method according to claim 35, wherein the cattle is Norwegian Red cattle.
 44. A (isolated) cattle gamete, comprising within its genome at least one allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition; wherein the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #242-P #246, P #311, P #312, P #314-P #334, P #339, P #340, P #343, P #344 and P #346-481 listed in table
 1. 45. The (isolated) cattle gamete according to claim 44, wherein the at least one allele is a “non-fat allele” for C:16:0 and a “fat allele” for C18:1 cis9.
 46. The (isolated) cattle gamete according to claim 44, wherein the (isolated) cattle gamete is a cattle semen, a cattle sperm or a cattle ovum.
 47. The (isolated) cattle gamete according to claim 44, wherein the (isolated) cattle gamete is a cattle ovum.
 48. A (isolated) cattle, comprising within its genome at least one allele which in a female milk-producing cattle is indicative of a desired milk fatty acid composition; wherein the at least one allele is an allele of at least one polymorphism selected from the group consisting of P #242-P #246, P #311, P #312, P #314-P #334, P #339, P #340, P #343, P #344 and P #346-481 listed in table
 1. 49. The (isolated) cattle according to claim 48, wherein the (isolated) cattle is a (isolated) female milk-producing cattle.
 50. The (isolated) cattle according to claim 48, wherein the (isolated) cattle is a (isolated) male cattle.
 51. The (isolated) cattle according to claim 48, wherein the at least one allele is a “non-fat allele” for C:16:0 and a “fat allele” for C18:1 cis9.
 52. Milk produced by the (isolated) cattle according to claim 48, wherein the cattle is a female milk-producing cattle. 